Thyristor Theory & Design Considerations Handbook

Thyristor Theory and Design Considerations
Handbook
HBD855/D
Rev. 1, Nov−2006
© SCILLC, 2005
Previous Edition © 2005 as Excerpted from DL137/D
“All Rights Reserved’’
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1
ABOUT THYRISTORS
capacitor discharge ignitors, engine ignition systems, and
many other kinds of equipment.
Although thyristors of all sorts are generally rugged,
there are several points to keep in mind when designing
circuits using them. One of the most important is to
respect the devices’ rated limits on rate of change of
voltage and current (dv/dt and di/dt). If these are
exceeded, the thyristor may be damaged or destroyed. On
the other hand, it is important to provide a trigger pulse
large enough and fast enough to turn the gate on quickly
and completely. Usually the gate trigger current should be
at least 50 percent greater than the maximum rated gate
trigger current. Thyristors may be driven in many
different ways, including directly from transistors or logic
families, power control integrated circuits, by
optoisolated triac drivers, programmable unijunction
transistors (PUTs) and SIDACs. These and other design
considerations are covered in this manual.
Of interest too, is a new line of Thyristor Surge
Suppressors in the surface mount SMB package covering
surge currents of 50, 80 and 100 amps, with breakover
voltages from 77 to 400 volts. NP Series Thyristor Surge
Protector Devices (TSPD) protect telecommunication
circuits such as central office, access, and customer
premises equipment from overvoltage conditions. These
are bidirectional devices so they are able to have
functionality of 2 devices in one package, saving valuable
space on board layout. These devices will act as a crowbar
when overvoltage occurs and will divert the energy away
from circuit or device that is being protected. Use of the
NP Series in equipment will help meet various regulatory
requirements
including:
GR−1089−CORE,
IEC
61000−4−5, ITU K.20/21/45, IEC 60950, TIA−968−A,
FCC Part 68, EN 60950, UL 1950. See ON
Semiconductor application note AND8022/D for
additional information.
Thyristors can take many forms, but they have certain
things in common. All of them are solid state switches
which act as open circuits capable of withstanding the
rated voltage until triggered. When they are triggered,
thyristors become low−impedance current paths and
remain in that condition until the current either stops or
drops below a minimum value called the holding level.
Once a thyristor has been triggered, the trigger current can
be removed without turning off the device.
Silicon controlled rectifiers (SCRs) and triacs are both
members of the thyristor family. SCRs are unidirectional
devices where triacs are bidirectional. An SCR is
designed to switch load current in one direction, while a
triac is designed to conduct load current in either
direction.
Structurally, all thyristors consist of several alternating
layers of opposite P and N silicon, with the exact structure
varying with the particular kind of device. The load is
applied across the multiple junctions and the trigger
current is injected at one of them. The trigger current
allows the load current to flow through the device, setting
up a regenerative action which keeps the current flowing
even after the trigger is removed.
These characteristics make thyristors extremely useful
in control applications. Compared to a mechanical switch,
a thyristor has a very long service life and very fast turn
on and turn off times. Because of their fast reaction times,
regenerative action and low resistance once triggered,
thyristors are useful as power controllers and transient
overvoltage protectors, as well as simply turning devices
on and off. Thyristors are used in motor controls,
incandescent lights, home appliances, cameras, office
equipment, programmable logic controls, ground fault
interrupters,
dimmer
switches,
power
tools,
telecommunication equipment, power supplies, timers,
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CHAPTER 1
Theory and Applications
Sections 1 thru 9
Page
Section 1: Symbols and Terminology . . . . . . . . . . . . . . 4
Section 2: Theory of Thyristor Operation . . . . . . . . . 10
Basic Behavior . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Switching Characteristics . . . . . . . . . . . . . . . . . . . . . . 13
False Triggering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Theory of SCR Power Control . . . . . . . . . . . . . . . . . . 16
Triac Theory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Methods of Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Zero Point Switching Techniques . . . . . . . . . . . . . . . . 25
Section 3: Thyristor Drivers and Triggering . . . . . . . 29
Pulse Triggering of SCRs . . . . . . . . . . . . . . . . . . . . . . 29
Effect of Temperature, Voltage and Loads . . . . . . . . 33
Using Negative Bias and Shunting . . . . . . . . . . . . . . . 35
Snubbing Thyristors . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Using Sensitive Gate SCRs . . . . . . . . . . . . . . . . . . . . 40
Drivers: Programmable Unijunction
Transistors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Section 4: The SIDAC, A New High Voltage
Bilateral Trigger . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
Section 5: SCR Characteristics . . . . . . . . . . . . . . . . . . 60
SCR Turn−Off Characteristics . . . . . . . . . . . . . . . . . . . 60
SCR Turn−Off Mechanism . . . . . . . . . . . . . . . . . . . . . 60
SCR Turn−Off Time tq . . . . . . . . . . . . . . . . . . . . . . . . . 60
Parameters Affecting tq . . . . . . . . . . . . . . . . . . . . . . . . 65
Characterizing SCRs for Crowbar Applications . . . . 71
Switches as Line−Type Modulators . . . . . . . . . . . . . . 79
Parallel Connected SCRs . . . . . . . . . . . . . . . . . . . . . . 85
RFI Suppression in Thyristor Circuits . . . . . . . . . . . . 89
Section 6: Applications . . . . . . . . . . . . . . . . . . . . . . . . . 93
Phase Control with Thyristors . . . . . . . . . . . . . . . . . . . 93
Motor Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
Phase Control with Trigger Devices . . . . . . . . . . . . . 102
Cycle Control with Optically Isolated
Triac Drivers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
AC Power Control with Solid−State Relays . . . . . . . 110
Triacs and Inductive Loads . . . . . . . . . . . . . . . . . . . . 114
Inverse Parallel SCRs for Power Control . . . . . . . . 117
Page
Interfacing Digital Circuits to Thyristor
Controlled AC Loads . . . . . . . . . . . . . . . . . . . . . . . . . 118
DC Motor Control with Thyristors . . . . . . . . . . . . . . . 127
Programmable Unijunction Transistor (PUT)
Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
Triac Zero−Point Switch Applications . . . . . . . . . . . 136
AN1045 — Series Triacs in AC High Voltage
Switching Circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
AN1048 — RC Snubber Networks for Thyristor
Power Control and Transient Suppression . . . . . . . 152
AND8005 — Automatic AC Line Voltage
Selector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 174
AND8006 — Electronic Starter for Flourescent
Lamps . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177
AND8007 — Momentary Solid State Switch
for Split Phase Motors . . . . . . . . . . . . . . . . . . . . . . . . . 181
AND8008 — Solid State Control Solutions
for Three Phase 1 HP Motor . . . . . . . . . . . . . . . . . . . 186
AND8015 — Long Life Incandescent Lamps
using SIDACs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 194
AND8017 — Solid State Control for
Bi−Directional Motors . . . . . . . . . . . . . . . . . . . . . . . . . 198
Section 7: Mounting Techniques for Thyristors . . . 201
Mounting Surface Considerations . . . . . . . . . . . . . . 202
Thermal Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . 203
Insulation Considerations . . . . . . . . . . . . . . . . . . . . . 204
Fastening Techniques . . . . . . . . . . . . . . . . . . . . . . . . 209
Insulated Packages . . . . . . . . . . . . . . . . . . . . . . . . . . 210
Surface Mount Devices . . . . . . . . . . . . . . . . . . . . . . . 212
Thermal System Evaluation . . . . . . . . . . . . . . . . . . . 214
Section 8: Reliability and Quality . . . . . . . . . . . . . . . . 218
Using Transient Thermal Resistance Data in
High Power Pulsed Thyristor Applications . . . . . . . 218
Thyristor Construction . . . . . . . . . . . . . . . . . . . . . . . . 230
In−Process Controls and Inspections . . . . . . . . . . . 230
Reliability Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231
Stress Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233
Environmental Testing . . . . . . . . . . . . . . . . . . . . . . . . 233
Section 9: Appendices . . . . . . . . . . . . . . . . . . . . . . . . . 234
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SECTION 1
SYMBOLS AND TERMINOLOGY
SYMBOLS
The following are the most commonly used schematic symbols for Thyristors:
Name of Device
Symbol
G
Silicon Controlled
Rectifier (SCR)
A
K
MT2
Triac
MT1
G
Thyristor Surge Protective
Devices & Sidac
MT1
MT2
G
Programmable Unijunction
Transistor (PUT)
A
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K
THYRISTOR TERMINOLOGY (The following terms are used in SCR and TRIAC specifications.)
Symbol
Terminology
Definition
di/dt
CRITICAL RATE OF RISE OF ON−STATE
CURRENT
The maximum rate of change of current the device will
withstand after switching from an off−state to an on−state
when using recommended gate drive. In other words, the
maximum value of the rate of rise of on−state current
which a Triac or SCR can withstand without damage.
(di/dt)c
RATE OF CHANGE OF COMMUTATING
CURRENT (Triacs)
Is the ability of a Triac to turn off itself when it is driving an
inductive load and a resultant commutating dv/dt condition associated with the nature of the load.
dv/dt
CRITICAL RATE OF RISE OF OFF−STATE
VOLTAGE
Also, commonly called static dv/dt. It is the minimum
value of the rate of rise of forward voltage which will
cause switching from the off−state to the on−state with
gate open.
IDRM
PEAK REPETITIVE BLOCKING CURRENT
The maximum value of current which will flow at VDRM
and specified temperature when the SCR or Triac is in the
off−state. Frequently referred to as leakage current in the
forward off−state blocking mode.
IGM
FORWARD PEAK GATE CURRENT (SCR)
PEAK GATE CURRENT (Triac)
The maximum peak gate current which may be safely
applied to the device to cause conduction.
IGT
GATE TRIGGER CURRENT
The maximum value of gate current required to switch the
device from the off−state to the on−state under specified
conditions. The designer should consider the maximum
gate trigger current as the minimum trigger current value
that must be applied to the device in order to assure its
proper triggering.
IH
HOLDING CURRENT
The minimum current that must be flowing (MT1 & MT2;
cathode and anode) to keep the device in a regenerative
on−state condition. Below this holding current value the
device will return to a blocking state, off condition.
IL
LATCHING CURRENT
The minimum current that must be applied through the
main terminals of a Triac (or cathode and anode of an
SCR) in order to turn from the off−state to the on−state
while its IGT is being correctly applied.
IRRM
PEAK REPETITIVE REVERSE BLOCKING
CURRENT
The maximum value of current which will flow at VRRM and
specified temperature when the SCR or Triac is in the
reverse mode, off−state. Frequently referred to as leakage
current in the reverse off−state blocking mode.
IT(AV)
AVERAGE ON−STATE CURRENT (SCR)
The maximum average on−state current the device may
safely conduct under stated conditions without incurring
damage.
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THYRISTOR TERMINOLOGY (The following terms are used in SCR and TRIAC specifications.)
Symbol
Terminology
Definition
ITM
PEAK REPETITIVE ON−STATE CURRENT (SCR)
(also called PEAK DISCHARGE CURRENT)
Peak discharge current capability of a thyristor useful
when connected to discharge peak current usually from a
capacitor. This is a rarely specified parameter. (See
MCR68 and MCR69 data sheets, for examples where it is
specified.)
IT(RMS)
ON−STATE RMS CURRENT
The maximum value of on−state rms current that can be
applied to the device through the two main terminals of a
Triac (or cathode and anode if an SCR) on a continuous
basis.
ITSM
PEAK NON−REPETITIVE SURGE CURRENT
The maximum allowable non−repetitive surge current the
device will withstand at a specified pulse width, usually
specified at 60 Hz.
I2t
CIRCUIT FUSING CONSIDERATIONS
(Current squared time)
The maximum forward non−repetitive overcurrent capability that the device is able to handle without damage.
Usually specified for one−half cycle of 60 Hz operation.
PG(AV)
FORWARD AVERAGE GATE POWER (SCR)
AVERAGE GATE POWER (Triac)
The maximum allowable value of gate power, averaged
over a full cycle, that may be dissipated between the gate
and cathode terminal (SCR), or main terminal 1 if a Triac.
PGM
FORWARD PEAK GATE POWER (SCR)
PEAK GATE POWER (Triac)
The maximum instantaneous value of gate power
dissipation between gate and cathode terminal for an
SCR or between gate and a main terminal MT1 for a
Triac, for a short pulse duration.
RθCA
THERMAL RESISTANCE,
CASE−TO−AMBIENT
The thermal resistance (steady−state) from the device
case to the ambient.
RθJA
THERMAL RESISTANCE,
JUNCTION−TO−AMBIENT
The thermal resistance (steady−state) from the semiconductor junction(s) to the ambient.
RθJC
THERMAL RESISTANCE,
JUNCTION−TO−CASE
The thermal resistance (steady−state) from the semiconductor junction(s) to a stated location on the case.
RθJM
THERMAL RESISTANCE,
JUNCTION−TO−MOUNTING SURFACE
The thermal resistance (steady−state) from the semiconductor junction(s) to a stated location on the mounting
surface.
TA
AMBIENT TEMPERATURE
The air temperature measured below a device in an
environment of substantially uniform temperature,
cooled only by natural air currents and not materially
affected by radiant and reflective surfaces.
TC
CASE TEMPERATURE
The temperature of the device case under specified
conditions.
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THYRISTOR TERMINOLOGY (The following terms are used in SCR and TRIAC specifications.)
Symbol
Terminology
Definition
tgt
TURN−ON TIME (SCR)
(Also called Gate Controlled Turn−on Time)
The time interval between a specified point at the
beginning of the gate pulse and the instant when the
device voltage has dropped to a specified low value
during the switching of an SCR from the off state to the
on state by a gate pulse.
TJ
OPERATING JUNCTION TEMPERATURE
The junction temperature of the device at the die level as
a result of ambient and load conditions. In other words,
the junction temperature must be operated within this
range to prevent permanent damage.
tq
TURN−OFF TIME (SCR)
The time interval between the instant when the SCR
current has decreased to zero after external switching of
the SCR voltage circuit and the instant when the thyristor
is capable of supporting a specified wave form without
turning on.
Tstg
STORAGE TEMPERATURE
The minimum and maximum temperature at which the
device may be stored without harm with no electrical
connections.
VDRM
PEAK REPETITIVE OFF−STATE FORWARD
VOLTAGE
The maximum allowed value of repetitive forward voltage
which may be applied and not switch the SCR or Triac on
or do damage to the thyristor.
VGD
GATE NON−TRIGGER VOLTAGE
At the maximum rated operational temperature, and at a
specified main terminal off−state voltage applied, this
parameter specifies the maximum DC voltage that can
be applied to the gate and still not switch the device from
off−state to and on−state.
VGM
FORWARD PEAK GATE VOLTAGE (SCR)
PEAK GATE VOLTAGE (Triac)
The maximum peak value of voltage allowed between
the gate and cathode terminals with these terminals
forward biased for an SCR. For a Triac, a bias condition
between the gate and main terminal MT1.
VGT
GATE TRIGGER VOLTAGE
The gate dc voltage required to produce the gate trigger
current.
V(Iso)
RMS ISOLATION VOLTAGE
The dielectric withstanding voltage capability of a
thyristor between the active portion of the device and the
heat sink. Relative humidity is a specified condition.
VRGM
PEAK REVERSE GATE BLOCKING
VOLTAGE (SCR)
The maximum allowable peak reverse voltage applied to
the gate on an SCR. Measured at a specified IGR which
is the reverse gate current.
VRRM
PEAK REPETITIVE REVERSE OFF−STATE
VOLTAGE
The maximum allowed value of repetitive reverse voltage
which may be applied and not switch the SCR or Triac on
or do damage to the thyristor.
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THYRISTOR TERMINOLOGY (The following terms are used in SCR and TRIAC specifications.)
Symbol
Terminology
Definition
VTM
PEAK FORWARD ON−STATE VOLTAGE (SCR)
PEAK ON−STATE VOLTAGE (Triac)
The maximum voltage drop across the main terminals at
stated conditions when the devices are in the on−state
(i.e., when the thyristor is in conduction). To prevent
heating of the junction, the VTM is measured at a short
pulse width and low duty cycle.
ZθJA(t)
TRANSIENT THERMAL IMPEDANCE,
JUNCTION−TO−AMBIENT
The transient thermal impedance from the semiconductor junction(s) to the ambient.
ZθJC(t)
TRANSIENT THERMAL IMPEDANCE,
JUNCTION−TO−CASE
The transient thermal impedance from the semiconductor junction(s) to a stated location on the case.
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Thyristor Surge Protector Devices (TSPD) and Sidac Terminology*
Symbol
Terminology
Definition
IBO
BREAKOVER CURRENT
The breakover current IBO is the corresponding parameter defining the VBO condition, that is, where breakdown
is occurring.
ID1, ID2
OFF−STATE CURRENT (TSPD)
The maximum value of current which will flow at specific
voltages (VD1 and VD2) when the TSPD is clearly in the
off−state. Frequently referred to as leakage current.
Ipps
PULSE SURGE SHORT CIRCUIT CURRENT
NON−REPETITIVE (TSPD)
The maximum pulse surge capability of the TSPD
(non−repetitive) under double exponential decay waveform conditions.
Ppk
INSTANTANEOUS PEAK POWER
DISSIPATION (TSPD)
Defines the instantaneous peak power dissipation when
the TSPD (thyristor surge suppressor devices) are
subjected to specified surge current conditions.
Rs
SWITCHING RESISTANCE (Sidac)
The effective switching resistance usually under a
sinusoidal, 60 Hz condition.
VBO
BREAKOVER VOLTAGE
It is the peak voltage point where the device switches to
an on−state condition.
V(BR)
BREAKDOWN VOLTAGE (TSPD)
VBR is the voltage where breakdown occurs. Usually
given as a typical value for reference to the Design
Engineer.
VDM
OFF−STATE VOLTAGE (TSPD)
The maximum off−state voltage prior to the TSPD going
into a characteristic similar to an avalanche mode. When
a transient or line signal exceeds the VDM, the device
begins to avalanche, then immediately begins to
conduct.
VT
ON−STATE VOLTAGE (TSPD)
The maximum voltage drop across the terminals at
stated conditions when the TSPD devices are in the
on−state (i.e., conduction). To prevent overheating, VT is
measured at a short pulse width and a low duty cycle.
* All of the definitions on this page are for ones that were not already previously defined under Triac and SCR terminology.
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SECTION 2
THEORY OF THYRISTOR OPERATION
Edited and Updated
schematic symbol for an SCR, and Figure 2.1(b) shows
the P−N−P−N structure the symbol represents. In the
two−transistor model for the SCR shown in Figure 2.1(c),
the interconnections of the two transistors are such that
regenerative action occurs. Observe that if current is
injected into any leg of the model, the gain of the
transistors (if sufficiently high) causes this current to be
amplified in another leg. In order for regeneration to
occur, it is necessary for the sum of the common base
current gains (α) of the two transistors to exceed unity.
Therefore, because the junction leakage currents are
relatively small and current gain is designed to be low at
the leakage current level, the PNPN device remains off
unless external current is applied. When sufficient trigger
current is applied (to the gate, for example, in the case of
an SCR) to raise the loop gain to unity, regeneration
occurs and the on−state principal current is limited
primarily by external circuit impedance. If the initiating
trigger current is removed, the thyristor remains in the on
state, providing the current level is high enough to meet
the unity gain criteria. This critical current is called
latching current.
In order to turn off a thyristor, some change in current
must occur to reduce the loop gain below unity. From the
model, it appears that shorting the gate to cathode would
accomplish this. However in an actual SCR structure, the
gate area is only a fraction of the cathode area and very
little current is diverted by the short. In practice, the
principal current must be reduced below a certain level,
called holding current, before gain falls below unity and
turn−off may commence.
In fabricating practical SCRs and Triacs, a “shorted
emitter” design is generally used in which, schematically,
a resistor is added from gate to cathode or gate to MT1.
Because current is diverted from the N−base through the
resistor, the gate trigger current, latching current and
holding current all increase. One of the principal reasons
for the shunt resistance is to improve dynamic performance at high temperatures. Without the shunt, leakage
current on most high current thyristors could initiate
turn−on at high temperatures.
To successfully apply thyristors, an understanding of
their characteristics, ratings, and limitations is imperative.
In this chapter, significant thyristor characteristics, the
basis of their ratings, and their relationship to circuit
design are discussed.
Several different kinds of thyristors are shown in Table
2.1. Silicon Controlled Rectifiers (SCRs) are the most
widely used as power control elements; triacs are quite
popular in lower current (under 40 A) ac power applications. Diacs, SUSs and SBSs are most commonly used as
gate trigger devices for the power control elements.
Table 2.1. Thyristor Types
*JEDEC Titles
Popular Names, Types
Reverse Blocking Diode
Thyristor
{ Four Layer Diode, Silicon
{ Unilateral Switch (SUS)
Reverse Blocking Triode
Thyristor
{ Silicon Controlled Rectifier
{ (SCR)
Reverse Conducting Diode
Thyristor
{ Reverse Conducting Four
{ Layer Diode
Reverse Conducting Triode
Thyristor
{ Reverse Conducting SCR
Bidirectional Triode Thyristor
{ Triac
* JEDEC is an acronym for the Joint Electron Device Engineering
Councils, an industry standardization activity co−sponsored by the
Electronic Industries Association (EIA) and the National Electrical
Manufacturers Association (NEMA).
{ Not generally available.
Before considering thyristor characteristics in detail, a
brief review of their operation based upon the common
two−transistor analogy of an SCR is in order.
BASIC BEHAVIOR
The bistable action of thyristors is readily explained by
analysis of the structure of an SCR. This analysis is
essentially the same for any operating quadrant of triac
because a triac may be considered as two parallel SCRs
oriented in opposite directions. Figure 2.1(a) shows the
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from leakage, or avalanche breakdown of a blocking
junction. As a result, the breakover voltage of a thyristor
can be varied or controlled by injection of a current at the
gate terminal. Figure 2.2 shows the interaction of gate
current and voltage for an SCR.
When the gate current Ig is zero, the applied voltage
must reach the breakover voltage of the SCR before
switching occurs. As the value of gate current is
increased, however, the ability of a thyristor to support
applied voltage is reduced and there is a certain value of
gate current at which the behavior of the thyristor closely
resembles that of a rectifier. Because thyristor turn−on, as
a result of exceeding the breakover voltage, can produce
high instantaneous power dissipation non−uniformly
distributed over the die area during the switching
transition, extreme temperatures resulting in die failure
may occur unless the magnitude and rate of rise of
principal current (di/dt) is restricted to tolerable levels.
For normal operation, therefore, SCRs and triacs are
operated at applied voltages lower than the breakover
voltage, and are made to switch to the on state by gate
signals high enough to assure complete turn−on independent of the applied voltage. On the other hand, diacs and
other thyristor trigger devices are designed to be triggered
by anode breakover. Nevertheless they also have di/dt and
peak current limits which must be adhered to.
Sensitive gate thyristors employ a high resistance shunt
or none at all; consequently, their characteristics can be
altered dramatically by use of an external resistance. An
external resistance has a minor effect on most shorted
emitter designs.
ANODE
ANODE
GATE
CATHODE
(a)
P
IB1
IC2
IC1
IB2
ANODE
N
P
N
P
N
P
GATE
N
P
GATE
IK
N
(c)
CATHODE
(b)
CATHODE
Figure 2.1. Two−transistor analogy of an SCR:
(a) schematic symbol of SCR; (b) P−N−P−N structure
represented by schematic symbol; (c) two−transistor
model of SCR.
−
Junction temperature is the primary variable affecting thyristor characteristics. Increased temperatures
make the thyristor easier to turn on and keep on.
Consequently, circuit conditions which determine
turn−on must be designed to operate at the lowest
anticipated junction temperatures, while circuit conditions which are to turn off the thyristor or prevent false
triggering must be designed to operate at the maximum
junction temperature.
Thyristor specifications are usually written with case
temperatures specified and with electrical conditions such
that the power dissipation is low enough that the junction
temperature essentially equals the case temperature. It is
incumbent upon the user to properly account for changes
in characteristics caused by the circuit operating conditions different from the test conditions.
V
Ig4
Ig3
Ig2
Ig1 = 0
Figure 2.2. Thyristor Characteristics Illustrating
Breakover as a Function of Gate Current
A triac works the same general way for both positive
and negative voltage. However since a triac can be
switched on by either polarity of the gate signal regardless
of the voltage polarity across the main terminals, the
situation is somewhat more complex than for an SCR.
The various combinations of gate and main terminal
polarities are shown in Figure 2.3. The relative sensitivity
depends on the physical structure of a particular triac, but
as a rule, sensitivity is highest in quadrant I and quadrant
IV is generally considerably less sensitive than the others.
TRIGGERING CHARACTERISTICS
Turn−on of a thyristor requires injection of current to
raise the loop gain to unity. The current can take the form
of current applied to the gate, an anode current resulting
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MT2(+)
QUADRANT II
QUADRANT I
MT2(+), G(−)
MT2(+), G(+)
QUADRANT III
QUADRANT IV
MT2(−), G(−)
MT2(−), G(+)
G(−)
Although the criteria for turn−on have been described in
terms of current, it is more basic to consider the thyristor
as being charge controlled. Accordingly, as the duration
of the trigger pulse is reduced, its amplitude must be
correspondingly increased. Figure 2.5 shows typical
behavior at various pulse widths and temperatures.
The gate pulse width required to trigger a thyristor also
depends upon the time required for the anode current to
reach the latching value. It may be necessary to maintain
a gate signal throughout the conduction period in
applications where the load is highly inductive or where
the anode current may swing below the holding value
within the conduction period.
When triggering an SCR with a dc current, excess
leakage in the reverse direction normally occurs if the
trigger signal is maintained during the reverse blocking
phase of the anode voltage. This happens because the
SCR operates like a remote base transistor having a gain
which is generally about 0.5. When high gate drive
currents are used, substantial dissipation could occur in
the SCR or a significant current could flow in the load;
therefore, some means usually must be provided to
remove the gate signal during the reverse blocking phase.
G(+)
MT2(−)
Figure 2.3. Quadrant Definitions for a Triac
Gate sensitivity of a triac as a function of temperature is
shown in Figure 2.4.
20
OFF−STATE VOLTAGE = 12 Vdc
ALL QUADRANTS
300
IGTM , PEAK GATE CURRENT (mA)
IGT, GATE TRIGGER CURRENT (mA)
30
10
7
5
3
− 80 − 60
1
QUADRANT 2
3
4
− 40 − 20
0
20
40
60
80
TJ, JUNCTION TEMPERATURE (°C)
100
120
Figure 2.4. Typical Triac Triggering Sensitivity in the
Four Trigger Quadrants
OFF−STATE VOLTAGE = 12 V
100
70
50
30
TJ = −55°C
25°C
10
7
5
3
0.2
100°C
0.5
1
2
5
10 20
PULSE WIDTH (μs)
50
100 200
Figure 2.5. Typical Behavior of Gate Trigger Current as
Pulse Width and Temperature Are Varied
Since both the junction leakage currents and the current
gain of the “transistor” elements increase with temperature, the magnitude of the required gate trigger current
decreases as temperature increases. The gate — which
can be regarded as a diode — exhibits a decreasing
voltage drop as temperature increases. Thus it is important that the gate trigger circuit be designed to deliver
sufficient current to the gate at the lowest anticipated
temperature.
It is also advisable to observe the maximum gate
current, as well as peak and average power dissipation
ratings. Also in the negative direction, the maximum gate
ratings should be observed. Both positive and negative
gate limits are often given on the data sheets and they may
indicate that protective devices such as voltage clamps
and current limiters may be required in some applications.
It is generally inadvisable to dissipate power in the
reverse direction.
LATCH AND HOLD CHARACTERISTICS
In order for the thyristor to remain in the on state when
the trigger signal is removed, it is necessary to have
sufficient principal current flowing to raise the loop gain
to unity. The principal current level required is the
latching current, IL. Although triacs show some dependency on the gate current in quadrant II, the latching
current is primarily affected by the temperature on shorted
emitter structures.
In order to allow turn off, the principal current must be
reduced below the level of the latching current. The
current level where turn off occurs is called the holding
current, IH. Like the latching current, the holding current
is affected by temperature and also depends on the gate
impedance.
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Reverse voltage on the gate of an SCR markedly
increases the latch and hold levels. Forward bias on
thyristor gates may significantly lower the values shown
in the data sheets since those values are normally given
with the gate open. Failure to take this into account can
cause latch or hold problems when thyristors are being
driven from transistors whose saturation voltages are a
few tenths of a volt.
Thyristors made with shorted emitter gates are obviously not as sensitive to the gate circuit conditions as devices
which have no built−in shunt.
of the gate−trigger current and shows a relationship which
is roughly inversely proportional.
The rise time is influenced primarily by the off−state
voltage, as high voltage causes an increase in regenerative
gain. Of major importance in the rise time interval is the
relationship between principal voltage and current flow
through the thyristor di/dt. During this time the dynamic
voltage drop is high and the current density due to the
possible rapid rate of change can produce localized hot
spots in the die. This may permanently degrade the
blocking characteristics. Therefore, it is important that
power dissipation during turn−on be restricted to safe
levels.
Turn−off time is a property associated only with SCRs
and other unidirectional devices. (In triacs of bidirectional
devices a reverse voltage cannot be used to provide
circuit−commutated turn−off voltage because a reverse
voltage applied to one half of the structure would be a
forward−bias voltage to the other half.) For turn−off times
in SCRs, the recovery period consists of two stages, a
reverse recovery time and a gate or forward blocking
recovery time, as shown in Figure 2.7.
When the forward current of an SCR is reduced to zero
at the end of a conduction period, application of reverse
voltage between the anode and cathode terminals causes
reverse current flow in the SCR. The current persists until
the time that the reverse current decreases to the leakage
level. Reverse recovery time (trr) is usually measured
from the point where the principal current changes
polarity to a specified point on the reverse current
waveform as indicated in Figure 2.7. During this period
the anode and cathode junctions are being swept free of
charge so that they may support reverse voltage. A second
recovery period, called the gate recovery time, tgr, must
elapse for the charge stored in the forward−blocking
junction to recombine so that forward−blocking voltage
can be reapplied and successfully blocked by the SCR.
The gate recovery time of an SCR is usually much longer
than the reverse recovery time. The total time from the
instant reverse recovery current begins to flow to the start
of the forward−blocking voltage is referred to as circuit−
commutated turn−off time tq.
Turn−off time depends upon a number of circuit
conditions including on−state current prior to turn−off,
rate of change of current during the forward−to−reverse
transition, reverse−blocking voltage, rate of change of
reapplied forward voltage, the gate bias, and junction
temperature. Increasing junction temperature and on−
state current both increase turn−off time and have a more
SWITCHING CHARACTERISTICS
When triacs or SCRs are triggered by a gate signal, the
turn−on time consists of two stages: a delay time, td, and a
rise time, tr, as shown in Figure 2.6. The total gate
controlled turn−on time, tgt, is usually defined as the time
interval between the 50 percent point of the leading edge
of the gate trigger voltage and 90 percent point of the
principal current. The rise time tr is the time interval
required for the principal current to rise from 10 to 90
percent of its maximum value. A resistive load is usually
specified.
90% POINT
PRINCIPAL
VOLTAGE
10% POINT
0
90% POINT
PRINCIPAL
CURRENT
10% POINT
0
td
tr
ton
GATE
CURRENT
IGT
IGT
50%
50% POINT
0
(WAVESHAPES FOR A SENSITIVE LOAD)
Figure 2.6. Waveshapes Illustrating Thyristor Turn−On
Time For A Resistive Load
Delay time decreases slightly as the peak off−state
voltage increases. It is primarily related to the magnitude
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becomes a forward current to the second half of the triac.
The current resulting from stored charge causes the
second half of the triac to go into the conducting state in
the absence of a gate signal. Once current conduction has
been established by application of a gate signal, therefore,
complete loss in power control can occur as a result of
interaction within the N−type base region of the triac
unless sufficient time elapses or the rate of application of
the reverse polarity voltage is slow enough to allow nearly
all the charge to recombine in the common N−type region.
Therefore, triacs are generally limited to low−frequency
−60 Hz applications. Turn−off or commutation of triacs is
more severe with inductive loads than with resistive loads
because of the phase lag between voltage and current
associated with inductive loads. Figure 2.8 shows the
waveforms for an inductive load with lagging current
power factor. At the time the current reaches zero
crossover (Point A), the half of the triac in conduction
begins to commutate when the principal current falls
below the holding current. At the instant the conducting
half of the triac turns off, an applied voltage opposite the
current polarity is applied across the triac terminals (Point
B). Because this voltage is a forward bias to the second
half of the triac, the suddenly reapplied voltage in
conjunction with the remaining stored charge in the
high−voltage junction reduces the over−all device capability to support voltage. The result is a loss of power
control to the load, and the device remains in the
conducting state in absence of a gate signal. The measure
of triac turn−off ability is the rate of rise of the opposite
polarity voltage it can handle without remaining on. It is
called commutating dv/dt (dv/dt[c]). Circuit conditions
and temperature affect dv/dt(c) in a manner similar to the
way tq is affected in an SCR.
It is imperative that some means be provided to restrict
the rate of rise of reapplied voltage to a value which will
permit triac turn−off under the conditions of inductive
load. A commonly accepted method for keeping the
commutating dv/dt within tolerable levels is to use an RC
snubber network in parallel with the main terminals of the
triac. Because the rate of rise of applied voltage at the
triac terminals is a function of the load impedance and the
RC snubber network, the circuit can be evaluated under
worst−case conditions of operating case temperature and
maximum principal current. The values of resistance and
capacitance in the snubber area then adjusted so that the
rate of rise of commutating dv/dt stress is within the
specified minimum limit under any of the conditions
mentioned above. The value of snubber resistance should
be high enough to limit the snubber capacitance discharge
currents during turn−on and dampen the LC oscillation
during commutation. The combination of snubber values
having highest resistance and lowest capacitance that
provides satisfactory operation is generally preferred.
significant effect than any of the other factors. Negative
gate bias will decrease the turn−off time.
REAPPLIED
dv/dt
PRINCIPAL
VOLTAGE
FORWARD
0
REVERSE
di/dt
FORWARD
PRINCIPAL
CURRENT
0
REVERSE
trr
tgr
tq
Figure 2.7. Waveshapes Illustrating Thyristor
Turn−Off Time
For applications in which an SCR is used to control ac
power, during the entire negative half of the sine wave a
reverse voltage is applied. Turn off is easily accomplished
for most devices at frequencies up to a few kilohertz. For
applications in which the SCR is used to control the
output of a full−wave rectifier bridge, however, there is no
reverse voltage available for turn−off, and complete
turn−off can be accomplished only if the bridge output is
reduced close to zero such that the principal current is
reduced to a value lower than the device holding current
for a sufficiently long time. Turn−off problems may occur
even at a frequency of 60 Hz particularly if an inductive
load is being controlled.
In triacs, rapid application of a reverse polarity voltage
does not cause turn−off because the main blocking
junctions are common to both halves of the device. When
the first triac structure (SCR−1) is in the conducting state,
a quantity of charge accumulates in the N−type region as
a result of the principal current flow. As the principal
current crosses the zero reference point, a reverse current
is established as a result of the charge remaining in the
N−type region, which is common to both halves of the
device. Consequently, the reverse recovery current
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above the ratings of thyristors. Thyristors, in general,
switch from the off state to the on state whenever the
breakover voltage of the device is exceeded, and energy is
then transferred to the load. However, unless a thyristor is
specified for use in a breakover mode, care should be
exercised to ensure that breakover does not occur, as some
devices may incur surface damage with a resultant
degradation of blocking characteristics. It is good practice
when thyristors are exposed to a heavy transient environment to provide some form of transient suppression.
For applications in which low−energy, long−duration
transients may be encountered, it is advisable to use
thyristors that have voltage ratings greater than the
highest voltage transient expected in the system. The use
of voltage clipping cells (MOV or Zener) is also an
effective method to hold transient below thyristor ratings.
The use of an RC “snubber” circuit is effective in
reducing the effects of the high−energy short−duration
transients more frequently encountered. The snubber is
commonly required to prevent the static dv/dt limits from
being exceeded, and often may be satisfactory in limiting
the amplitude of the voltage transients as well.
For all applications, the dv/dt limits may not be
exceeded. This is the minimum value of the rate of rise
off−state voltage applied immediately to the MT1−MT2
terminals after the principal current of the opposing
polarity has decreased to zero.
SPURIOUS GATE SIGNALS: In noisy electrical
environments, it is possible for enough energy to cause
gate triggering to be coupled into the gate wiring by stray
capacitance or electromagnetic induction. It is therefore
advisable to keep the gate lead short and have the
common return directly to the cathode or MT1. In
extreme cases, shielded wire may be required. Another
aid commonly used is to connect a capacitance on the
order of 0.01 to 0.1 μF across the gate and cathode
terminals. This has the added advantage of increasing the
thyristor dv/dt capability, since it forms a capacitance
divider with the anode to gate capacitance. The gate
capacitor also reduces the rate of application of gate
trigger current which may cause di/dt failures if a high
inrush load is present.
IH
V
I
dr
c
dt
A
B
Figure 2.8. Inductive Load Waveforms
FALSE TRIGGERING
Circuit conditions can cause thyristors to turn on in the
absence of the trigger signal. False triggering may result
from:
1) A high rate of rise of anode voltage, (the dv/dt
effect).
2) Transient voltages causing anode breakover.
3) Spurious gate signals.
Static dv/dt effect: When a source voltage is suddenly
applied to a thyristor which is in the off state, it may
switch from the off state to the conducting state. If the
thyristor is controlling alternating voltage, false turn−on
resulting from a transient imposed voltage is limited to no
more than one−half cycle of the applied voltage because
turn−off occurs during the zero current crossing. However, if the principal voltage is dc voltage, the transient
may cause switching to the on state and turn−off could
then be achieved only by a circuit interruption.
The switching from the off state caused by a rapid rate
of rise of anode voltage is the result of the internal
capacitance of the thyristor. A voltage wavefront
impressed across the terminals of a thyristor causes a
capacitance−charging current to flow through the device
which is a function of the rate of rise of applied off−state
voltage (i = C dv/dt). If the rate of rise of voltage exceeds
a critical value, the capacitance charging current exceeds
the gate triggering current and causes device turn−on.
Operation at elevated junction temperatures reduces the
thyristor ability to support a steep rising voltage dv/dt
because of increased sensitivity.
dv/dt ability can be improved quite markedly in
sensitive gate devices and to some extent in shorted
emitter designs by a resistance from gate to cathode (or
MT1) however reverse bias voltage is even more effective
in an SCR. More commonly, a snubber network is used to
keep the dv/dt within the limits of the thyristor when the
gate is open.
TRANSIENT VOLTAGES: — Voltage transients
which occur in electrical systems as a result of disturbance on the ac line caused by various sources such as
energizing transformers, load switching, solenoid closure,
contractors and the like may generate voltages which are
THYRISTOR RATINGS
To insure long life and proper operation, it is important
that operating conditions be restrained from exceeding
thyristor ratings. The most important and fundamental
ratings are temperature and voltage which are interrelated
to some extent. The voltage ratings are applicable only up
to the maximum temperature ratings of a particular part
number. The temperature rating may be chosen by the
manufacturer to insure satisfactory voltage ratings,
switching speeds, or dv/dt ability.
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OPERATING CURRENT RATINGS
Current ratings are not independently established as a
rule. The values are chosen such that at a practical case
temperature the power dissipation will not cause the
junction temperature rating to be exceeded.
Various manufacturers may chose different criteria to
establish ratings. At ON Semiconductors, use is made of
the thermal response of the semiconductor and worst case
values of on−state voltage and thermal resistance, to
guarantee the junction temperature is at or below its rated
value. Values shown on data sheets consequently differ
somewhat from those computed from the standard
formula:
TC(max)
where
TC (max)
T (rated)
RθJC
PD(AV)
For a triac, the current waveform used in the rating is a
full sine wave. Multicycle surge curves are used to select
proper circuit breakers and series line impedances to
prevent damage to the thyristor in the event of an
equipment fault.
The subcycle overload or subcycle surge rating curve is
so called because the time duration of the rating is usually
from about one to eight milliseconds which is less than the
time of one cycle of a 60 Hz power source. Overload peak
current is often given in curve form as a function of
overload duration. This rating also applies following any
rated load condition and neither off−state nor reverse
blocking capability is required on the part of the thyristor
immediately following the overload current. The subcycle
surge current rating may be used to select the proper
current−limiting fuse for protection of the thyristor in the
event of an equipment fault. Since this use of the rating is
so common, manufacturers simply publish the i2t rating in
place of the subcycle current overload curve because
fuses are commonly rated in terms of i2t. The i2t rating
can be approximated from the single cycle surge rating
(ITSM) by using:
= T (rated) − RθJC PD(AV)
= Maximum allowable case temperature
= Rated junction temperature or maximum
rated case temperature with zero principal
current and rated ac blocking voltage
applied.
= Junction to case thermal resistance
= Average power dissipation
i2t = I2TSM t/2
The above formula is generally suitable for estimating
case temperature in situations not covered by data sheet
information. Worst case values should be used for thermal
resistance and power dissipation.
where the time t is the time base of the overload, i.e., 8.33
ms for a 60 Hz frequency.
Repetitive overloads are those which are an intended
part of the application such as a motor drive application.
Since this type of overload may occur a large number of
times during the life of the thyristor, its rated maximum
operating junction temperature must not be exceeded
during the overload if long thyristor life is required. Since
this type of overload may have a complex current
waveform and duty−cycle, a current rating analysis
involving the use of the transient thermal impedance
characteristics is often the only practical approach. In this
type of analysis, the thyristor junction−to−case transient
thermal impedance characteristic is added to the user’s
heat dissipator transient thermal impedance characteristic. Then by the superposition of power waveforms in
conjunction with the composite thermal impedance curve,
the overload current rating can be obtained. The exact
calculation procedure is found in the power semiconductor literature.
OVERLOAD CURRENT RATINGS
Overload current ratings may be divided into two types:
non−repetitive and repetitive.
Non−repetitive overloads are those which are not a part
of the normal application of the device. Examples of such
overloads are faults in the equipment in which the devices
are used and accidental shorting of the load. Non−repetitive overload ratings permit the device to exceed its
maximum operating junction temperature for short periods of time because this overload rating applies following
any rated load condition. In the case of a reverse blocking
thyristor or SCR, the device must block rated voltage in
the reverse direction during the current overload. However, no type of thyristor is required to block off−stage
voltage at any time during or immediately following the
overload. Thus, in the case of a triac, the device need not
block in either direction during or immediately following
the overload. Usually only approximately one hundred
such current overloads are permitted over the life of the
device. These non−repetitive overload ratings just
described may be divided into two types: multicycle
(which include single cycle) and subcycle. For an SCR,
the multicycle overload current rating, or surge current
rating as it is commonly called, is generally presented as a
curve giving the maximum peak values of half sine wave
on−state current as a function of overload duration
measured in number of cycles for a 60 Hz frequency.
THEORY OF SCR POWER CONTROL
The most common form of SCR power control is phase
control. In this mode of operation, the SCR is held in an
off condition for a portion of the positive half cycle and
then is triggered into an on condition at a time in the half
cycle determined by the control circuitry (in which the
circuit current is limited only by the load — the entire line
voltage except for a nominal one volt drop across the SCR
is applied to the load).
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CONTROL CHARACTERISTICS
One SCR alone can control only one half cycle of the
waveform. For full wave ac control, two SCRs are
connected in inverse parallel (the anode of each connected to the cathode of the other, see Figure 2.9a). For
full wave dc control, two methods are possible. Two SCRs
may be used in a bridge rectifier (see Figure 2.9b) or one
SCR may be placed in series with a diode bridge (see
Figure 2.9c).
Figure 2.10 shows the voltage waveform along with
some common terms used in describing SCR operation.
Delay angle is the time, measured in electrical degrees,
during which the SCR is blocking the line voltage. The
period during which the SCR is on is called the
conduction angle.
It is important to note that the SCR is a voltage
controlling device. The load and power source determine
the circuit current.
Now we arrive at a problem. Different loads respond to
different characteristics of the ac waveform. Some loads
are sensitive to peak voltage, some to average voltage and
some to rms voltage. Figures 2.11(b) and 2.12(b) show the
various characteristic voltages plotted against the conduction angle for half wave and full wave circuits. These
voltages have been normalized to the rms of the applied
voltage. To determine the actual peak, average or rms
voltage for any conduction angle, we simply multiply the
normalized voltage by the rms value of the applied line
voltage. (These normalized curves also apply to current in
a resistive circuit.) Since the greatest majority of circuits
are either 115 or 230 volt power, the curves have been
redrawn for these voltages in Figures 2.11(a) and 2.12(a).
A relative power curve has been added to Figure 2.12
for constant impedance loads such as heaters. (Incandescent lamps and motors do not follow this curve precisely
since their relative impedance changes with applied
voltage.) To use the curves, we find the full wave rated
power of the load, then multiply by the fraction associated
with the phase angle in question. For example, a 180°
conduction angle in a half wave circuit provides 0.5 x full
wave full−conduction power.
An interesting point is illustrated by the power curves.
A conduction angle of 30° provides only three per cent of
full power in a full wave circuit, and a conduction angle of
150° provides 97 per cent of full power. Thus, the control
circuit can provide 94 per cent of full power control with
a pulse phase variation of only 120°. Thus, it becomes
pointless in many cases to try to obtain conduction angles
less than 30° or greater than 150°.
The simplest and most common control circuit for
phase control is a relaxation oscillator. This circuit is
shown diagrammatically as it would be used with an SCR
in Figure 2.13. The capacitor is charged through the
resistor from a voltage or current source until the
breakover voltage of the trigger device is reached. At that
time, the trigger device changes to its on state, and the
capacitor is discharged through the gate of the SCR.
Turn−on of the SCR is thus accomplished with a short,
high current pulse. Commonly used trigger devices are
programmable unijunction transistors, silicon bilateral
switches, SIDACs, optically coupled thyristors, and
power control integrated circuits. Phase control can be
obtained by varying the RC time constant of a charging
circuit so that trigger device turn−on occurs at varying
phase angles within the controlled half cycle.
If the relaxation oscillator is to be operated from a pure
dc source, the capacitor voltage−time characteristic is
shown in Figure 2.14. This shows the capacitor voltage as
it rises all the way to the supply voltage through several
time constants. Figure 2.14(b) shows the charge characteristic in the first time constant greatly expanded. It is
this portion of the capacitor charge characteristic which is
most often used in SCR and Triac control circuits.
Generally, a design starting point is selection of a
capacitance value which will reliably trigger the thyristor
when the capacitor is discharged. Gate characteristics and
ratings, trigger device properties, and the load impedance
play a part in the selection. Since not all of the important
parameters for this selection are completely specified,
experimental determination is often the best method.
Low−current loads and strongly inductive circuits
sometimes cause triggering difficulty because the gate
current pulse goes away before the principal thyristor
current achieves the latching value. A series gate resistor
can be used to introduce a RC discharge time constant in
the gate circuit and lengthen trigger pulse duration
allowing more time for the main terminal current to rise to
the latching value. Small thyristors will require a series
gate resistance to avoid exceeding the gate ratings. The
discharge time constant of a snubber, if used, can also aid
latching. The duration of these capacitor discharge
duration currents can be estimated by
tw10 = 2.3 RC where tw10 = time for current to decay to
10% of the peak.
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LINE
CONTROL
CIRCUIT
LINE
LOAD
CONTROL
CIRCUIT
(a)
ac Control
LOAD
(c)
One SCR dc Control
Figure 2.9. SCR Connections For Various Methods
Of Phase Control
FULL WAVE RECTIFIED OPERATION
VOLTAGE APPLIED TO LOAD
CONTROL
CIRCUIT
LINE
DELAY ANGLE
LOAD
CONDUCTION ANGLE
(b)
Two SCR dc Control
Figure 2.10. Sine Wave Showing Principles
Of Phase Control
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APPLIED
VOLTAGE
230 V 115 V
360 180
1.8
HALF WAVE
320
160
1.4
280
140
1.2
240
120
1
200
100
160
80
120
60
80
40
40
20
0
0
PEAK VOLTAGE
VOLTAGE
NORMALIZED SINE WAVE rms VOLTAGE
POWER AS FRACTION OF FULL CONDUCTION
1.6
HALF WAVE
rms
0.8
0.6
POWER
rms
0.4
0.2
AVG
0
0
20
40
(a)
PEAK VOLTAGE
60 80 100 120 140 160 180
CONDUCTION ANGLE
AVG
0
20
40
(b)
60 80 100 120 140 160 180
CONDUCTION ANGLE
Figure 2.11. Half−Wave Characteristics Of Thyristor Power Control
APPLIED
VOLTAGE
230 V 115 V
360 180
1.8
FULL WAVE
FULL WAVE
320
160
1.4
280
140
1.2
240
120
200
100
160
80
120
60
PEAK VOLTAGE
1
VOLTAGE
NORMALIZED SINE WAVE rms VOLTAGE
POWER AS FRACTION OF FULL CONDUCTION
1.6
rms
0.8
POWER
0.6
PEAK VOLTAGE
rms
AVG
AVG
0.4
80
40
0.2
40
20
0
0
0
0
(a)
20
40
60 80 100 120 140 160 180
CONDUCTION ANGLE
0
(b)
20
40
60 80 100 120 140 160 180
CONDUCTION ANGLE
Figure 2.12. Full−Wave Characteristics Of Thyristor Power Control
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In many of the recently proposed circuits for low cost
operation, the timing capacitor of the relaxation oscillator
is charged through a rectifier and resistor using the ac
power line as a source. Calculations of charging time with
this circuit become exceedingly difficult, although they
are still necessary for circuit design. The curves of
Figure 2.14 simplify the design immensely. These curves
show the voltage−time characteristic of the capacitor
charged from one half cycle of a sine wave. Voltage is
normalized to the rms value of the sine wave for
convenience of use. The parameter of the curves is a new
term, the ratio of the RC time constant to the period of one
half cycle, and is denoted by the Greek letter τ. It may
most easily be calculated from the equation
τ = 2RCf. Where:
R = resistance in Ohms
C = capacitance in Farads
f = frequency in Hertz.
1
0.9
0.7
0.7
0.6
0.6
CAPACITOR VOLTAGE AS
FRACTION OF SUPPLY VOLTAGE
CAPACITOR VOLTAGE AS
FRACTION OF SUPPLY VOLTAGE
0.8
0.5
0.4
0.3
0.2
0.4
0.3
0.2
0.1
0.1
0
0.5
0
0
1
2
3
4
TIME CONSTANTS
5
0
6
0.2
0.4
0.6
0.8
TIME CONSTANTS
Figure 2.13(b). Expanded Scale
Figure 2.13(a). Capacitor Charging From dc Source
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1
1.2
1.80
NORMALIZED VOLTAGE AS A FRACTION OF
rms CHARGING SOURCE VOLTAGE
APPLIED VOLTAGE, V
R
1.40
V
τ = 0.1
VC
C
0.2
1.20
1
CAPACITOR
VOLTAGE, VC
0.3
0.4
0.5
0.80
0.7
0.707
0.60
1
1.5
0.40
2
3
5
0.20
0
0
180
20
160
40
140
60
120
80
100
100
80
120
60
140
40
30
160
20
180
0
DELAY ANGLE IN DEG.
CONDUCTION ANGLE IN DEG.
Figure 2.14(a). Capacitor Voltage When Charged
0.35
NORMALIZED VOLTAGE AS A FRACTION OF
rms CHARGING SOURCE VOLTAGE
τ = 0.1
0.2
0.3
0.5
0.7
1.5
1
2
2.5
0.30
3
0.25
4
0.20
5
0.15
7
0.10
10
15
0.05
20
50
0
0
180
20
160
40
140
60
120
80
100
100
80
120
60
140
40
160
20
180
0
DELAY ANGLE IN DEG.
CONDUCTION ANGLE IN DEG.
Figure 2.14(b). Expansion of Figure 2.15(a).
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NORMALIZED VOLTAGE AS A FRACTION OF
rms CHARGING SOURCE VOLTAGE
0.1
τ = 0.1 0.2
0.09
0.3 0.7 1 1.5
2 2.5
3
5
4
7
8.5
0.5
0.08
0.0696
0.07
10
12.5
0.06
15
0.05
20
0.04
0.03
35
0.02
50
0.01
0
0
10
20
30
40
50
60
70
180
170
160
150
140
130
120
110
80
90
100
110
120
130
140
150
160
170
180
100
90
80
70
60
50
40
30
20
10
0
rms CHARGING SOURCE VOLTAGE
DELAY ANGLE
IN DEG.
CONDUCTION
ANGLE IN DEG.
Figure 2.14(c). Expansion of Figure 2.14(b)
To use the curves when starting the capacitor charge from
zero each half cycle, a line is drawn horizontally across
the curves at the relative voltage level of the trigger
breakdown compared to the rms sine wave voltage. The τ
is determined for maximum and minimum conduction
angles and the limits of R may be found from the equation
for τ.
An example will again clarify the picture. Consider the
same problem as the previous example, except that the
capacitor charging source is the 115 Vac, 60 Hz power
line.
The ratio of the trigger diode breakover voltage to the
RMS charging voltage is then
can be prevented by selecting a lower value resistor and
larger capacitor. The available current can be determined
from Figure 2.14(a). The vertical line drawn from the
conduction angle of 30° intersects the applied voltage
curve at 0.707. The instantaneous current at breakover is
then
I = (0.707 115−8)/110 k = 733 μA.
When the conduction angle is greater than 90°,
triggering takes place before the peak of the sine wave. If
the current thru the SBS does not exceed the switching
current at the moment of breakover, triggering may still
take place but not at the predicted time because of the
additional delay for the rising line voltage to drive the
SBS current up to the switching level. Usually long
conduction angles are associated with low value timing
resistors making this problem less likely. The SBS current
at the moment of breakover can be determined by the
same method described for the trailing edge.
It is advisable to use a shunt gate−cathode resistor
across sensitive gate SCR’s to provide a path for leakage
currents and to insure that firing of the SCR causes
turn−on of the trigger device and discharge of the gate
circuit capacitor.
8/115 = 69.6 10−3.
A line drawn at 0.0696 on the ordinate of Figure 2.14(c)
shows that for a conduction angle of 30°, τ = 12, and for a
conduction angle of 150°, τ = 0.8. Therefore, since
R = τ/(2CF)
Rmax 12
100 k ohms,
–
2(1.0 10 6)60
Rmin 0.8
6667 ohms.
2(1 10–6 )60
These values would require a potentiometer of 100 k in
series with a 6.2 k minimum fixed resistance.
The timing resistor must be capable of supplying the
highest switching current allowed by the SBS specification at the switching voltage.
When the conduction angle is less than 90°, triggering
takes place along the back of the power line sine wave and
maximum firing current thru the SBS is at the start of SBS
breakover. If this current does not equal or exceed “ls” the
SBS will fail to trigger and phase control will be lost. This
TRIAC THEORY
The triac is a three−terminal ac semiconductor switch
which is triggered into conduction when a low−energy
signal is applied to its gate. Unlike the silicon controlled
rectifier or SCR, the triac will conduct current in either
direction when turned on. The triac also differs from the
SCR in that either a positive or negative gate signal will
trigger the triac into conduction. The triac may be thought
of as two complementary SCRs in parallel.
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direction. If this voltage is exceeded, even transiently, the
triac may go into conduction without a gate signal.
Although the triac is not damaged by this action if the
current is limited, this situation should be avoided
because control of the triac is lost. A triac for a particular
application should have VDRM at least as high as the peak
of the ac waveform to be applied so reliable control can be
maintained. The holding current (IH) is the minimum
value of current necessary to maintain conduction. When
the current goes below IH, the triac ceases to conduct and
reverse to the blocking state. IDRM is the leakage current
of the triac with VDRM applied from MT2 to MT1 and is
several orders of magnitude smaller than the current
rating of the device. The figure shows the characteristic of
the triac without a gate signal applied but it should be
noted that the triac can be triggered into the on state at any
value of voltage up to VDRM by the application of a gate
signal. This important characteristic makes the triac very
useful.
Since the triac will conduct in either direction and can
be triggered with either a positive or negative gate signal
there are four possible triggering modes (Figure 2.3):
Quadrant I; MT2(+), G(+), positive voltage and positive
gate current. Quadrant II; MT2(+), G(−), positive
voltage and negative gate current. Quadrant III;
MT2(−), G(−), negative voltage and negative gate
current. Quadrant IV; MT2(−), G(+), negative voltage
and positive gate current.
Present triacs are most sensitive in quadrants I and III,
slightly less so in quadrant II, and much less sensitive in
quadrant IV. Therefore it is not recommended to use
quadrant IV unless special circumstances dictate it.
An important fact to remember is that since a triac can
conduct current in both directions, it has only a brief
interval during which the sine wave current is passing
through zero to recover and revert to its blocking state.
For this reason, reliable operation of present triacs is
limited to 60 Hz line frequency and lower frequencies.
For inductive loads, the phase−shift between the current
and voltage means that at the time the current falls below
IH and the triac ceases to conduct, there exists a certain
voltage which must appear across the triac. If this voltage
appears too rapidly, the triac will resume conduction and
control is lost. In order to achieve control with certain
inductive loads, the rate of rise in voltage (dv/dt) must be
limited by a series RC network across the triac. The
capacitor will then limit the dv/dt across the triac. The
resistor is necessary to limit the surge of current from the
capacitor when the triac fires, and to damp the ringing of
the capacitance with the load inductance.
The triac offers the circuit designer an economical and
versatile means of accurately controlling ac power. It has
several advantages over conventional mechanical
switches. Since the triac has a positive “on” and a zero
current “off” characteristic, it does not suffer from the
contact bounce or arcing inherent in mechanical switches.
The switching action of the triac is very fast compared to
conventional relays, giving more accurate control. A triac
can be triggered by dc, ac, rectified ac or pulses. Because
of the low energy required for triggering a triac, the
control circuit can use any of many low−cost solid−state
devices such as transistors, bilateral switches, sensitive−
gate SCRs and triacs, optically coupled drivers and
integrated circuits.
CHARACTERISTICS OF THE TRIAC
Figure 2.15(a) shows the triac symbol and its relationship to a typical package. Since the triac is a bilateral
device, the terms “anode” and “cathode” used for
unilateral devices have no meaning. Therefore, the
terminals are simply designated by MT1, MT2, and G,
where MT1 and MT2 are the current−carrying terminals,
and G, is the gate terminal used for triggering the triac. To
avoid confusion, it has become standard practice to
specify all currents and voltages using MT1 as the
reference point.
The basic structure of a triac is shown in Figure 2.15(b).
This drawing shows why the symbol adopted for the triac
consists of two complementary SCRs with a common
gate. The triac is a five−layer device with the region
between MT1 and MT2 being P−N−P−N switch (SCR) in
parallel with a N−P−N−P switch (complementary SCR).
Also, the structure gives some insight into the triac’s
ability to be triggered with either a positive or negative
gate signal. The region between MT1 and G consists of
two complementary diodes. A positive or negative gate
signal will forward−bias one of these diodes causing the
same transistor action found in the SCR. This action
breaks down the blocking junction regardless of the
polarity of MT1. Current flow between MT2 and MT1
then causes the device to provide gate current internally. It
will remain on until this current flow is interrupted.
The voltage−current characteristic of the triac is shown
in Figure 2.16 where, as previously stated, MT1 is used as
the reference point. The first quadrant, Q−I, is the region
where MT2 is positive with respect to MT1 and quadrant
III is the opposite case. Several of the terms used in
characterizing the triac are shown on the figure. VDRM is
the breakover voltage of the device and is the highest
voltage the triac may be allowed to block in either
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MT2
PHASE CONTROL
An effective and widely−used method of controlling the
average power to a load through the triac is by phase
control. Phase control is a method of utilizing the triac to
apply the ac supply to the load for a controlled fraction of
each cycle. In this mode of operation, the triac is held in
an off or open condition for a portion of each positive and
negative cycle, and then is triggered into an on condition
at a time in the half cycle determined by the control
circuitry. In the on condition, the circuit current is limited
only by the load — i.e., the entire line voltage (less the
forward drop of the triac) is applied to the load.
Figure 2.17 shows the voltage waveform along with
some common terms used in describing triac operation.
Delay angle is the angle, measured in electrical degrees,
during which the triac is blocking the line voltage. The
period during which the triac is on is called the
conduction angle.
It is important to note that the triac is either off
(blocking voltage) or fully on (conducting). When it is in
the on condition, the circuit current is determined only by
the load and the power source.
As one might expect, in spite of its usefulness, phase
control is not without disadvantages. The main disadvantage of using phase control in triac applications is the
generation of electro−magnetic interference (EMI). Each
time the triac is fired the load current rises from zero to
the load−limited current value in a very short time. The
resulting di/dt generates a wide spectrum of noise which
may interfere with the operation of nearby electronic
equipment unless proper filtering is used.
GATE
MT1
(a)
MT2
N
P
N
P
N
N
MT1
G
(b)
Figure 2.15. Triac Structure and Symbol
ON−STATE
IDRM
VDRM
I
Q1
MT2+
BLOCKING
STATE
VDRM
IH
V
IH
ZERO POINT SWITCHING
IDRM
In addition to filtering, EMI can be minimized by
zero−point switching, which is often preferable. Zero−
point switching is a technique whereby the control
element (in this case the triac) is gated on at the instant the
sine wave voltage goes through zero. This reduces, or
eliminates, turn−on transients and the EMI. Power to the
load is controlled by providing bursts of complete sine
waves to the load as shown in Figure 2.18. Modulation
can be on a random basis with an on−off control, or a
proportioning basis with the proper type of proportional
control.
In order for zero−point switching to be effective, it must
indeed be zero point switching. If a triac is turned on with
as little as 10 volts across it into a load of a few−hundred
watts, sufficient EMI will result to nullify the advantages
of adopting zero−point switching in the first place.
BLOCKING STATE
QIII
MT2ON−STATE
Figure 2.16. Triac Voltage−Current Characteristic
METHODS OF CONTROL
AC SWITCH
A useful application of triac is as a direct replacement
for an ac mechanical relay. In this application, the triac
furnishes on−off control and the power−regulating ability
of the triac is not utilized. The control circuitry for this
application is usually very simple, consisting of a source
for the gate signal and some type of small current switch,
either mechanical or electrical. The gate signal can be
obtained from a separate source or directly from the line
voltage at terminal MT2 of the triac.
BASIC TRIAC AC SWITCHES
Figure 2.19 shows methods of using the triac as an
on−off switch. These circuits are useful in applications
where simplicity and reliability are important. As previously stated, there is no arcing with the triac, which can
be very important in some applications. The circuits are
for resistive loads as shown and require the addition of a
dv/dt network across the triac for inductive loads.
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Figure 2.19(a) shows low−voltage control of the triac.
When switch S1 is closed, gate current is supplied to the
triac from the 10 volt battery. In order to reduce surge
current failures during turn on (ton), this current should be
5 to 10 times the maximum gate current (IGT) required to
trigger the triac.
The triac turns on and remains on until S1 is opened.
This circuit switches at zero current except for initial turn
on. S1 can be a very−low−current switch because it carries
only the triac gate current.
Figure 2.19(b) shows a triac switch with the same
characteristics as the circuit in Figure 2.19(a) except the
need for a battery has been eliminated. The gate signal is
obtained from the voltage at MT2 of the triac prior to turn
on.
The circuit shown in Figure 2.19(c) is a modification of
Figure 2.19(b). When switch S1 is in position one, the
triac receives no gate current and is non−conducting. With
S1 in position two, circuit operation is the same as that for
Figure 2.19(b). In position three, the triac receives gate
current only on positive half cycles. Therefore, the triac
conducts only on positive half cycles and the power to the
load is half wave.
Figure 2.19(d) shows ac control of the triac. The pulse
can be transformer coupled to isolate power and control
circuits. Peak current should be 10 times IGT(max) and the
RC time constant should be 5 times ton(max). A high
frequency pulse (1 to 5 kHz) is often used to obtain zero
point switching.
applied to the load as shown in Figure 2.20. This type of
switching is primarily used to control power to resistive
loads such as heaters. It can also be used for controlling
the speed of motors if the duty cycle is modulated by
having short bursts of power applied to the load and the
load characteristic is primarily inertial rather than frictional. Modulation can be on a random basis with an
on−off control, or on a proportioning basis with the proper
type of proportioning control.
In order for zero−point switching to be effective, it must
be true zero−point switching. If an SCR is turned on with
an anode voltage as low as 10 volts and a load of just a
few hundred watts, sufficient EMI will result to nullify the
advantages of going to zero−point switching in the first
place. The thyristor to be turned on must receive gate
drive exactly at the zero crossing of the applied voltage.
The most successful method of zero−point thyristor
control is therefore, to have the gate signal applied before
the zero crossing. As soon as the zero crossing occurs,
anode voltage will be supplied and the thyristor will come
on. This is effectively accomplished by using a capacitor
to derive a 90° leading gate signal from the power line
source. However, only one thyristor can be controlled
from this phase−shifted signal, and a slaving circuit is
necessary to control the other SCR to get full−wave power
control. These basic ideas are illustrated in Figure 2.21.
The slaving circuit fires only on the half cycle after the
firing of the master SCR. This guarantees that only
complete cycles of power will be applied to the load. The
gate signal to the master SCR receives all the control; a
convenient control method is to replace the switch with a
low−power transistor, which can be controlled by bridge−
sensing circuits, manually controlled potentiometers, or
various other techniques.
VOLTAGE APPLIED TO LOAD
LOAD
VOLTAGE
DELAY ANGLE
CONDUCTION ANGLE
HALF POWER TO LOAD
Figure 2.17. Sine Wave Showing Principles
of Phase Control
LINE
VOLTAGE
ZERO POINT SWITCHING TECHNIQUES
FULL POWER TO LOAD
Zero−point switches are highly desirable in many
applications because they do not generate electro−magnetic interference (EMI). A zero−point switch controls
sine−wave power in such a way that either complete
cycles or half cycles of the power supply voltage are
Figure 2.18. Sine Wave Showing Principles of
Zero−Point Switching
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15 Ω
LOAD
LOAD VOLTAGE
R1
47 Ω
115 VAC
60 Hz
S1
2N6346
LINE VOLTAGE
+
10 V
(a): Low Voltage Controlled Triac Switch
Figure 2.20. Load Voltage and Line Voltage for
25% Duty Cycle
15 Ω
LOAD
A basic SCR is very effective and trouble free.
However, it can dissipate considerable power. This must
be taken into account in designing the circuit and its
packaging.
In the case of triacs, a slaving circuit is also usually
required to furnish the gate signal for the negative half
cycle. However, triacs can use slave circuits requiring less
power than do SCRs as shown in Figure 2.21. Other
considerations being equal, the easier slaving will sometimes make the triac circuit more desirable than the SCR
circuit.
Besides slaving circuit power dissipation, there is
another consideration which should be carefully checked
when using high−power zero−point switching. Since this
is on−off switching, it abruptly applies the full load to the
power line every time the circuit turns on. This may cause
a temporary drop in voltage which can lead to erratic
operation of other electrical equipment on the line (light
dimming, TV picture shrinkage, etc.). For this reason,
loads with high cycling rates should not be powered from
the same supply lines as lights and other voltage−sensitive
devices. On the other hand, if the load cycling rate is slow,
say once per half minute, the loading flicker may not be
objectionable on lighting circuits.
A note of caution is in order here. The full−wave
zero−point switching control illustrated in Figure 2.21
should not be used as a half−wave control by removing
the slave SCR. When the slave SCR in Figure 2.21 is
removed, the master SCR has positive gate current
flowing over approximately 1/4 of a cycle while the SCR
itself is in the reverse−blocking state. This occurs during
the negative half cycle of the line voltage. When this
condition exists, Q1 will have a high leakage current with
full voltage applied and will therefore be dissipating high
power. This will cause excessive heating of the SCR and
may lead to its failure. If it is desirable to use such a
circuit as a half−wave control, then some means of
clamping the gate signal during the negative half cycle
must be devised to inhibit gate current while the SCR is
reverse blocking. The circuits shown in Figures 2.23 and
2.24 do not have this disadvantage and may be used as
half−wave controls.
R1
100 Ω
115 VAC
60 Hz
S1
2N6342
(b): Triac ac Static Contactor
15 Ω
LOAD
S1
115 VAC
60 Hz
3
2
1
2N6342
R1
100 Ω
(c): 3 Position Static Switch
15 Ω
LOAD
R1
2N6346
(d): AC Controlled Triac Switch
Figure 2.19. Triac Switches
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OPERATION
AC LINE
2 μF
200 V
150
1W
LOAD
Q1
(MASTER)
The zero−point switches shown in Figure 2.23 and 2.24
are used to insure that the control SCR turns on at the start
of each positive alternation. In Figure 2.23 a pulse is
generated before the zero crossing and provides a small
amount of gate current when line voltage starts to go
positive. This circuit is primarily for sensitive−gate SCRs.
Less−sensitive SCRs, with their higher gate currents,
normally require smaller values for R1 and R2 and the
result can be high power dissipation in these resistors. The
circuit of Figure 2.24 uses a capacitor, C2, to provide a
low−impedance path around resistors R1 and R2 and can
be used with less−sensitive, higher−current SCRs without
increasing the dissipation. This circuit actually oscillates
near the zero crossing point and provides a series of pulses
to assure zero−point switching.
The basic circuit is that shown in Figure 2.23.
Operation begins when switch S1 is closed. If the positive
alternation is present, nothing will happen since diode D1
is reverse biased. When the negative alternation begins,
capacitor C1 will charge through resistor R2 toward the
limit of voltage set by the voltage divider consisting of
resistors R1 and R2. As the negative alternation reaches
its peak, C1 will have charged to about 40 volts. Line
voltage will decrease but C1 cannot discharge because
diode D2 will be reverse biased. It can be seen that C1 and
three−layer diode D4 are effectively in series with the
line. When the line drops to 10 volts, C1 will still be 40
volts positive with respect to the gate of Q1. At this time
D4 will see about 30 volts and will trigger. This allows C1
to discharge through D3, D4, the gate of Q1, R2, and R1.
This discharge current will continue to flow as the line
voltage crosses zero and will insure that Q1 turns on at the
start of the positive alternation. Diode D3 prevents
reverse gate−current flow and resistor R3 prevents false
triggering.
The circuit in Figure 2.24 operates in a similar manner
up to the point where C1 starts to discharge into the gate.
The discharge path will now be from C1 through D3, D4,
R3, the gate of Q1, and capacitor C2. C2 will quickly
charge from this high pulse of current. This reduces the
voltage across D4 causing it to turn off and again revert to
its blocking state. Now C2 will discharge through R1 and
R2 until the voltage on D4 again becomes sufficient to
cause it to break back. This repetitive exchange of charge
from C1 to C2 causes a series of gate−current pulses to
flow as the line voltage crosses zero. This means that Q1
will again be turned on at the start of each positive
alternation as desired. Resistor R3 has been added to limit
the peak gate current.
Q2
(SLAVE)
Figure 2.21. Slave and Master SCRs for
Zero−Point Switching
1.2 k
7W
AC LINE
2 μF
200 V
MAC210A8
150
1W
ON−OFF
CONTROL
LOAD
Figure 2.22. Triac Zero−Point Switch
S1
AC
LINE
LOAD
D1
1N4004
C1
D4
0.25 μF 1N5760
R1
3.8 k
R2
8.2 k
1W
D2
1N4004
D3
1N4004
Q1
MCR22−6
R3
1k
Figure 2.23. Sensitive−Gate Switch
S1
AC
LINE
C1
0.25 μF
200 V
D1
1N4004
C2
10 nF
200 V
R1
3.8 k
R2
8.2 k
1W
LOAD
D3
D4
1N4004 1N5760
D2
1N4004
Q1
MCR218−4
R3
100
Figure 2.24. Zero−Point Switch
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AN SCR SLAVING CIRCUIT
C1 is being charged, D1 reverse−biases the base−emitter
junction of Q3, thereby holding it off. The charging time
constant, R1, C1, is set long enough that C1 charges for
practically the entire half cycle. The charging rate of C1
follows an “S” shaped curve, charging slowly at first, then
faster as the supply voltage peaks, and finally slowly
again as the supply voltage decreases. When the supply
voltage falls below the voltage across C1, diode D1
becomes reverse biased and the base−emitter of Q3
becomes forward biased. For the values shown, this
occurs approximately 6° before the end of the half cycle
conduction of Q1. The base current is derived from the
energy stored in C1. This turns on Q3, discharging C1
through Q3 and into the gate of Q2. As the voltage across
C1 decreases, the base drive of Q3 decreases and
somewhat limits the collector current. The current pulse
must last until the line voltage reaches a magnitude such
that latching current will exist in Q2. The values shown
will deliver a current pulse which peaks at 100 mA and
has a magnitude greater than 50 mA when the anode−
cathode voltage of Q2 reaches plus 10 volts. This circuit
completely discharges C1 during the half cycle that Q2 is
on. This eliminates the possibility of Q2 being slaved for
additional half cycles after the drive is removed from Q1.
The peak current and the current duration are controlled
by the values of R1 and C1. The values chosen provide
sufficient drive for “shorted emitter” SCRs which typically require 10 to 20 mA to fire. The particular SCR used
must be capable of handling the maximum current
requirements of the load to be driven; the 8 ampere, 200 V
SCRs shown will handle a 1000 watt load.
An SCR slaving circuit will provide full−wave control
of an ac load when the control signal is available to only
one of a pair of SCRs. An SCR slaving circuit is
commonly used where the master SCR is controlled by
zero−point switching. Zero−point switching causes the
load to receive a full cycle of line voltage whenever the
control signal is applied. The duty cycle of the control
signal therefore determines the average amount of power
supplied to the load. Zero−point switching is necessary for
large loads such as electric heaters because conventional
phase−shift techniques would generate an excessive
amount of electro−magnetic interference (EMI).
This particular slaving circuit has two important
advantages over standard RC discharge slaving circuits. It
derives these advantages with practically no increase in
price by using a low−cost transistor in place of the
current−limiting resistor normally used for slaving. The
first advantage is that a large pulse of gate current is
available at the zero−crossing point. This means that it is
not necessary to select sensitive−gate SCRs for controlling power. The second advantage is that this current
pulse is reduced to zero within one alternation. This has a
couple of good effects on the operation of the slaving
SCR. It prevents gate drive from appearing while the SCR
is reverse−biased, which would produce high power
dissipation within the device. It also prevents the slaved
SCR from being turned on for additional half cycles after
the drive is removed from the control SCR.
OPERATION
The SCR slaving circuit shown in Figure 2.25 provides
a single power pulse to the gate of SCR Q2 each time SCR
Q1 turns on, thus turning Q2 on for the half cycle
following the one during which Q1 was on. Q2 is
therefore turned on only when Q1 is turned on, and the
load can be controlled by a signal connected to the gate of
Q1 as shown in the schematic. The control signal an be
either dc or a power pulse. If the control signal is
synchronized with the power line, this circuit will make
an excellent zero−point switch. During the time that Q1 is
on, capacitor C1 is charged through R1, D1 and Q1. While
1000 W MAX
10 k
2W
R1
1N4004
120 VAC
60 Hz
Q1
2N6397
INPUT SIGNAL
+ 5 μF
C1
50 V
CONTROL
SCR
Q2
2N6397
Q3
MPS
3638
*1000 WATT LOAD. SEE TEXT.
Figure 2.25. SCR Slave Circuit
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SECTION 3
THYRISTOR DRIVERS AND TRIGGERING
1.0
Edited and Updated
W ≥ BASE WIDTH
L ≥ DIFFUSION LENGTH
Triggering a thyristor requires meeting its gate energy
specifications and there are many ways of doing this. In
general, the gate should be driven hard and fast to ensure
complete gate turn on and thus minimize di/dt effects.
Usually this means a gate current of at least three times
the gate turn on current with a pulse rise of less than one
microsecond and a pulse width greater than 10 microseconds. The gate can also be driven by a dc source as long
as the average gate power limits are met.
Some of the methods of driving the gate include:
1) Direct drive from logic families of transistors
2) Opto triac drivers
3) Programmable unijunction transistors (PUTs)
4) SIDACs
a , COMMON BASE CURRENT GAIN
0.8
W 0.1
L
0.6
W 0.5
L
W 1.0
L
0.4
0.2
In this chapter we will discuss all of these, as well as
some of the important design and application considerations in triggering thyristors in general. In the chapter
on applications, we will also discuss some additional
considerations relating to drivers and triggers in
specific applications.
0
10−3
10−2
10−1
1.0
EMITTER CURRENT DENSITY
10
102
(mA/mm2)
Figure 3.1. Typical Variation of Transistor α with
Emitter Current Density
PULSE TRIGGERING OF SCRs
Using the two transistor analysis, the anode current, IA,
can be expressed as a function of gate current, IG, as:
GATE TURN−ON MECHANISM
The turn−on of PNPN devices has been discussed in many
papers where it has been shown that the condition of
IA switching is given by dv = 0 (i.e., α1 + α2 = 1, where α1
di
a 2 IG ICS1 ICS2
1 a1 a2
(1)
Definitions and derivations are given in Appendix I.
Note that the anode current, IA, will increase to infinity as
α1 + α2 = 1. This analysis is based upon the assumption
that no majority carrier current flows out of the gate
circuit. When no such assumption is made, the condition
for turn−on is given by:
and α2 are the current amplification factors of the two
“transistors.’’ However, in the case of an SCR connected
to a reverse gate bias, the device can have α1 + α2 = 1 and
still stay in the blocking state. The condition of turn−on is
actually α1 + α2 1.
The current amplification factor, α, increases with
emitter current; some typical curves are shown in
Figure 3.1. The monotonical increase of α with IE of the
device in the blocking state makes the regeneration of
current (i.e., turn−on) possible.
IK
I
A
1 a1
a2
which corresponds to α1 + α2 1 (see Appendix I).
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(2)
J1
J2
J3
CURRENT PULSE TRIGGERING
IK
IA
P1
N1
P2
Current pulse triggering is defined as supplying current
through the gate to compensate for the carriers lost by
recombination in order to provide enough current to
sustain increasing regeneration. If the gate is triggered
with a current pulse, shorter pulse widths require higher
currents as shown by Figure 3.3(a). Figure 3.3(a) seems
to indicate there is a constant amount of charge required
to trigger on the device when IG is above a threshold level.
When the charge required for turn−on plotted versus
pulse current or pulse width, there is an optimum range of
current levels or pulse widths for which the charge is
minimum, as shown in region A of Figure 3.3(b) and (c).
Region C shows that for lower current levels (i.e., longer
minimum pulse widths) more charge is required to trigger
on the device. Region B shows increasing charge required
as the current gets higher and the pulse width smaller.
N2
ANODE
(A)
CATHODE
(K)
IG
GATE (G)
Figure 3.2. Schematic Structure of an SCR, Positive
Currents Are Defined as Shown by the Arrows
Current regeneration starts when charge or current is
introduced through the gate (Figure 3.2). Electrons are
injected from the cathode across J3 ; they travel across
the P2 “base’’ region to be swept out by the collector
junction, J2, and thrown into the N1 base. The increase of
majority carrier electrons in region N1 decreases the
potential in region N1, so that holes from P1 are injected
across the junction J1, into the N1 “base’’ region to be
swept across J2, and thrown into the P2 “base’’ region.
The increase in the potential of region P2 causes more
electrons to be injected into P2 , thereby repeating the
cycle. Since α increases with the emitter current, an
increase of regeneration takes place until α1 + α2 1.
Meanwhile, more carriers are collected than emitted from
either of the emitters. The continuity of charge flow is
violated and there is an electron build−up on the N1 side
of J2 , and a hole build−up on the P2 side. When the inert
impurity charges are compensated for by injected
majority carriers, the junction J2 becomes forward
biased. The collector emits holes back to J1 and electrons
to J3 until a steady state continuity of charge is
established.
During the regeneration process, the time it takes for a
minority carrier to travel across a base region is the transit
time, t, which is given approximately as:
W 2i
t1 2Di
where Wi base width
Di diffusion length
100
i G , MINIMUM GATE TRIGGER CURRENT (mA)
VAK = 10 V
TA = 25°C
80
60
HIGH UNIT
40
LOW
UNIT
20
IG THRESHOLD
0
0.05
(3)
0.1
0.2
0.5
1.0
2.0
5.0
t, PULSE WIDTH (ms)
(The subscript “i’’ can be either 1 or 2 to indicate the
appropriate base.) The time taken from the start of the
gate trigger to the turn−on of the device will be equal to
some multiple of the transit time.
Figure 3.3(a). Typical Variation of Minimum Gate
Current Required to Trigger
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30
10
100
100
VAK = 10 V
TA = 25°C
50
VAK = 10 V
T = 25°C
50
Q in , MINIMUM TRIGGER CHARGE (nc)
I G THRESHOLD
LOW
UNIT
20
HIGH UNIT
C
A
B
10
5.0
IG THRESHOLD
Q in, MINIMUM TRIGGER CHARGE (nc)
HIGH UNIT
2.0
C
A
B
(Q = it)
20
B
A
C
10
LOW
UNIT
5.0
2.0
1.0
1.0
2.0
5.0
10
20
50
0.05
100
iG, GATE CURRENT (mA)
0.1
0.2
0.5
1.0
2.0
5.0
10
t, MINIMUM PULSE WIDTH (ms)
Figure 3.3(b). Variation of Charge versus Gate Current
Figure 3.3(c). Variation of Charge versus Minimum
Pulse Width
The charge characteristic curves can be explained
qualitatively by the variation of current amplification
(α T) with respect to emitter current. A typical variation
of α 1 and α 2 for a thyristor is shown in Figure 3.4(a).
From Figure 3.4(a), it can be deduced that the total
current amplification factor, αT = α1 + α2, has a
characteristic curve as shown in Figure 3.4(b). (The data
does not correspond to the data of Figure 3.3 — they are
taken for different types of devices.)
The gate current levels in region A of Figure 3.3
correspond to the emitter (or anode) currents for which
the slope of the αT curve is steepest (Figure 3.4(b)). In
region A the rate that αT builds up with respect to changes
of IE (or IA) is high, little charge is lost by recombination,
and therefore, a minimum charge is required for turn−on.
In region C of Figure 3.3, lower gate current corresponds to small IE (or IA) for which the slope of αT, as
well as αT itself, is small. It takes a large change in IE (or
IA) in order to build up αT. In this region, a lot of the
turn−on the device should be large enough to flood the
gate to cathode junction nearly instantaneously with a
charge supplied through the gate is lost by recombination.
The charge required for turn−on increases markedly as the
gate current is decreased to the threshold level. Below this
threshold, the device will not turn on regardless of how
long the pulse width becomes. At this point, the slope of
αT is equal to zero; all of the charge supplied is lost
completely in recombination or drained out through
gate−cathode shunt resistance. A qualitative analysis of
variation of charge with pulse width at region A and C is
discussed in Appendix II.
In region B, as the gate current level gets higher and the
pulse width smaller, there are two effects that contribute
to an increasing charge requirement to trigger−on the
device: (1) the decreasing slope of αT and, (2) the transit
time effect. As mentioned previously, it takes some
multiple of the transit time for turn−on. As the gate pulse
width decreases to N (tN1 + tP2) or less, (where N is a
positive real number, tN1 = transit time of base N1, and tP2 =
transit time of base P2) the amount of current required to
charge which corresponds to IE (or IA) high enough to
give αT 1.
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1.0
1.4
N−P−N SECTION a2
1.2
a , CURRENT AMPLIFICATION FACTOR
a , CURRENT AMPLIFICATION FACTOR
0.8
0.6
0.4
P−N−P SECTION a1
B
1.0
A
0.8
C
0.6
0.4
0.2
0.2
0
0
0.1
1.0
10
100
300
0.1
1.0
IE, EMITTER CURRENT (mA)
100
300
IE, EMITTER CURRENT (mA)
Figure 3.4(a). The Variation of α1 and α2 with Emitter
Current for the Two Sections of Two Typical
Silicon Controlled Rectifiers
CAPACITANCE CHARGE TRIGGERING
Figure 3.4(b). Typical Variation of αT versus
Emitter Current
capacitance used as shown in Figure 3.7. Two reasons
may account for the increasing charge characteristics:
Using a gate trigger circuit as shown in Figure 3.5, the
charge required for turn−on increases with the value of
1) An effect due to threshold current.
2) An effect due to variation of gate spreading resistance.
90%
DV2
rG2 R
TO
COMMUTATING
CIRCUIT
DV1
rG1 R
DV1
rG1 R
10%
S
S
S
e t
(rG1 R S)C1
DV2
rG2 R
ÉÉÉÉ
ÇÇÇÇ
ÉÉÉÉ
ÇÇÇÇ
ÉÉÉÉ
ÇÇÇÇ
I
e
S
t
(rG2 R )C 2
S
Ithr
II
tf1
SCR
RS
10
tf2
PULSE WIDTH, t
C
tfi = 2.2 (r′G1 + RS)C1
D V1
SHADED AREA I = |(r′G1 + RS)(C1)|(Ithr)
SHADED AREA II = |(r′G2 + RS)(C2)|(Ithr)
0
C 1 C2
DV1C 1 DV2C 2
|(r′G1 + RS)(C1)|(Ithr) < |(r′G2 + RS)(C2) |(Ithr)
Figure 3.5. Gate Circuit of Capacitance Charge
Triggering
Figure 3.6. Gate Current Waveform in Capacitance
Charge Triggering
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NORMALIZED GATE SPREADING RESISTANCE
Consider the gate current waveform in Figure 3.6; the
triggering pulse width is made large enough such that
τtfl; the threshold trigger current is shown as Ithr. All
of the charge supplied at a transient current level less than
Ithr is lost by recombination, as shown in the shaded
regions.
The gate spreading resistance (r′G) of the gate junction
varies inversely with peak current; the higher the peak
current, the smaller the gate spreading resistance. Variation of gate spreading resistance measured by the method
of Time Domain Reflectometry is plotted in Figure 3.8.
From the data of Figure 3.7, it is clear that for larger
values of capacitance a lower voltage level is required
for turn−on. The peak current of the spike in Figure 3.6 is
3.0
2.0
1.0
0.7
Results
are
plotted
0.1
Q in , MINIMUM TRIGGER CHARGE, Q(nc)
5.0
LOW UNIT
2.0
PULSE WIDTH = 50 ms
1.0
200
500
1000
2000
200
500
1000
The higher the temperature, the less charge required to
turn on the device, as shown in Figure 3.10. At the range
of temperatures where the SCR is operated the life time of
minority carriers increases with temperature; therefore
less charge into the gate is lost in recombination.
As analyzed in Appendix II, there are three components
of charge involved in gate triggering: (1) Qr, charge lost in
recombination, (2) Qdr, charge drained out through the
built−in gate−cathode shunt resistance, (3) Qtr, net charge
for triggering. All of them are temperature dependent.
Since the temperature coefficient of voltage across a p−n
junction is small, Qdr may be considered invariant of
temperature. At the temperature range of operation, the
temperature is too low to give rise to significant impurity
gettering, lifetime increases with temperature causing Qr
to decrease with increasing temperature. Also, Qtr
decreases with increasing temperature because at a
constant current the αT of the device in the blocking state
increases with temperature;7 in other words, to attain αT =
1 at an elevated temperature, less anode current, hence
gate current [see equation (3) of Appendix I], is needed;
therefore, Qtr decreases. The input charge, being equal to
the sum of Qtr, Qr, and Qdr, decreases with increasing
temperature.
The minimum current trigger charge decreases roughly
exponentially with temperature. Actual data taken on an
MCR729 deviate somewhat from exponential trend
(Figure 3.10). At higher temperatures, the rate of decrease
is less; also for different pulse widths the rates of decrease
of Qin are different; for large pulse widths the recombination charge becomes more significant than that of small
pulse widths. As the result, it is expected and Figure 3.10
shows that Qin decreases more rapidly with temperature at
high pulse widths. These effects are analyzed in
7.0
100
100
EFFECT OF TEMPERATURE
in
HIGH UNIT
3.0
50
Figure 3.8. Variation of Gate Spreading Resistance
versus Gate Peak Current
15
VAK = 10 V
TA = −15°C
20
GATE CURRENT (mA)
Figure 3.9. As expected, r′G increases with increasing
values of capacitance used. Referring back to Figure 3.6,
for the same amount of charge (C ΔV), the larger the (Rs +
r′G)C time constant of the current spike, the more charge
under the threshold level is lost in recombination.
Increasing the value of C will increase the time constant
more rapidly than if r′G were invariant. Therefore,
increasing the value of C should increase the charge lost
as shown in Figure 3.7. Note that a two order of
magnitude increase in capacitance increased the charge
by less than 3:1.
10
Z0 = 50 W
0.3
0.2
Ipk. Smaller Ipk in turn yields large r′G, so that r′G is
dependent on the value of capacitance used in capacitance charge triggering. This reasoning is confirmed by
measuring the fall time of the gate trigger voltage and
calculating the transient gate spreading resistance, r′G,
tf
.
2.2 C
LOW UNIT
0.5
given by Ipk ΔV
; the smaller ΔV, the smaller
R s r′ G
from: Rs r′ G IA = 1 A
TA = 25°C
VAK = 10 V
HIGH UNIT
5000 10,000
C, CAPACITANCE (pF)
Figure 3.7. Variation of Trigger Charge versus
Capacitance Used
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EFFECT OF BLOCKING VOLTAGE
Appendix II [equation (7), page 235]. The theory and
experiment agree reasonably well.
An SCR is an avalanche mode device; the turn−on of
the device is due to multiplication of carriers in the
middle collector junction. The multiplication factor is
given by the empirical equation
40
M
VAK = 10 V
T = 25°C
r ′G , GATE SPREADING RESISTANCE (W )
where
(6)
M Multiplication factor
30
V Voltage across the middle “collector’’ junction
(voltage at which the device is blocking prior to
turn−on)
20
VB Breakdown voltage of the middle “collector’’
junction
t
(RS rG ) f
2.2C
n Some positive number
Note as V is increased, M also increases and in turn α
increases (the current amplification factor α = γδβM
where γ Emitter efficiency, β Base transport
factor, and δ Factor of recombination).
10
The larger the V, the larger is α T. It would be expected
for the minimum gate trigger charge to decrease with
increasing V. Experimental results show this effect (see
Figure 3.11). For the MCR729, the gate trigger charge is
only slightly affected by the voltage at which the device is
blocking prior to turn−on; this reflects that the exponent,
n, in equation (6) is small.
0
200
300
500
1000
2000
C, CAPACITANCE (pF)
Figure 3.9. Variation of Transient Base Spreading
Resistance versus Capacitance
20
EFFECT OF GATE CIRCUIT
VAK = 10 V
t = GATE CURRENT PULSE WIDTH
(Q = it)
Q in , MINIMUM TRIGGER CHARGE (nc)
·1
1 ( V )n
VB
10
9.0
As mentioned earlier, to turn on the device, the total
amplification factor must be greater than unity. This
means that if some current is being drained out of the gate
which bleeds the regeneration current, turn−on will be
affected. The higher the gate impedance, the less the gate
trigger charge. Since the regenerative current prior to
turn−on is small, the gate impedance only slightly affects
the required minimum trigger charge; but in the case of
over−driving the gate to achieve fast switching time, the
gate circuit impedance will have noticeable effect.
t = 1 ms
t = 300 ns
8.0
7.0
EFFECT OF INDUCTIVE LOAD
t = 500 ns
t = 100 ns
6.0
The presence of an inductive load tends to slow down
the change of anode current with time, thereby causing
the required charge for triggering to increase with the
value of inductance. For dc or long pulse width current
triggering, the inductive load has little effect, but its effect
increases markedly at short pulse widths, as shown in
Figure 3.12. The increase in charge occurs because at
short pulse widths, the trigger signal has decreased to a
negligible value before the anode current has reached a
level sufficient to sustain turn−on.
5.0
4.0
−15
+25
+65
+105
T, TEMPERATURE (°C)
Figure 3.10. Variation of Q versus Temperature
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10
9.0
8.0
7.0
USING NEGATIVE BIAS AND SHUNTING
6.0
Q in , MINIMUM TRIGGER CHARGE (nc)
Almost all SCR’s exhibit some degree of turn−off gain.
At normal values of anode current, negative gate current
will not have sufficient effect upon the internal feedback
loop of the device to cause any significant change in
anode current. However, it does have a marked effect at
low anode current levels; it can be put to advantage by
using it to modify certain device parameters. Specifically,
turn−off time may be reduced and hold current may be
increased. Reduction of turn−off time and increase of hold
current are useful in such circuits as inverters or in
full−wave phase control circuits in which inductance is
present.
Negative gate current may, of course, be produced by
use of an external bias supply. It may also be produced by
taking advantage of the fact that during conduction the
gate is positive with respect to the cathode and providing
an external conduction path such as a gate−to−cathode
resistor. All ON Semiconductor SCR’s, with the exception
of sensitive gate devices, are constructed with a built in
gate−to−cathode shunt, which produces the same effect as
negative gate current. Further change in characteristics
can be produced by use of an external shunt. Shunting
does not produce as much of a change in characteristics as
does negative bias, since the negative gate current, even
with an external short circuit, is limited by the lateral
resistance of the base layer. When using external negative
bias the current must be limited, and care must be taken to
avoid driving the gate into the avalanche region.
The effects of negative gate current are not shown on
the device specification sheets. The curves in Figure 3.13
represent measurements made on a number of SCRs, and
should therefore not be considered as spec limits. They
do, however, show definite trends. For example, all of the
SCRs showed an improvement in turn−off time of about
one−third by using negative bias up to the point where no
further significant improvement was obtained. The
increase in hold current by use of an external shunt
resistor ranged typically between 5 and 75 percent,
whereas with negative bias, the range of improvement ran
typically between 2−1/2 and 7 times the open gate value.
Note that the holding current curves are normalized and are
referred to the open gate value.
#1
#2
5.0
#3
4.0
3.0
2.0
TA = 25°C
PW = 500 ns
0.05 mF CAP. DISCHARGE
1.0
10
20
30
50
100
200
500
1000
VAK, ANODE VOLTAGE (V)
Figure 3.11. Variation of Current Trigger Charge
versus Blocking Voltage Prior to Turn−On
Q in , MINIMUM TRIGGER CHARGE (nc)
80
60
L = 100 mH
40
L = 10 mH
L = 0 mH
20
TA = 25°C
VAK = 10 V
0
30
50
70
100
200
300
500
700 1000
t, MINIMUM PULSE WIDTH (ns)
Figure 3.12. Effect of Inductance Load on
Triggering Charge
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SPREAD OF 5 DEVICES
REDUCING di/dt — EFFECT FAILURES
NORMALIZED HOLDING CURRENT
1.6
Figure 3.14 shows a typical SCR structural cross section
(not to scale). Note that the collector of transistor 1 and
the base of transistor 2 are one and the same layer. This is
also true for the collector of transistor 2 and the base of
transistor 1. Although for optimum performance as an
SCR the base thicknesses are great compared to a normal
transistor, nevertheless, base thickness is still small
compared to the lateral dimensions. When applying
positive bias to the gate, the transverse base resistance,
spreading resistance or rb′ will cause a lateral voltage drop
which will tend to forward bias those parts of the
transistor 1 emitter−junction closest to the base contact
(gate) more heavily, or sooner than the portions more
remote from the contact area. Regenerative action,
consequently will start in an area near the gate contact,
and the SCR will turn on first in this area. Once on,
conduction will propagate across the entire junction.
1.4
1.2
1.0
1.0
10
100
1000
5000
GATE−TO−CATHODE RESISTANCE (OHMS)
Figure 3.13(a). Normalized Holding Current
versus Gate−to−Cathode Resistance
SPREAD OF 5 DEVICES
NORMALIZED HOLDING CURRENT
6.0
LAYER
4.0
T1
CATHODE
(E)
NO. 3
(C)
(B)
NO. 2
(B)
(C)
NO. 1
(E)
GATE
ÉÉÉÉÉÉ
N
P
N
2.0
ÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉ
P
ANODE
0
0
−2.0
−4.0
−6.0
−8.0
Figure 3.14. Construction of Typical SCR
−10
GATE−TO−CATHODE VOLTAGE (VOLTS)
The phenomenon of di/dt failure is related to the
turn−on mechanism. Let us look at some of the external
factors involved and see how they contribute. Curve
3.15(a) shows the fall of anode−to−cathode voltage with
time. This fall follows a delay time after the application of
the gate bias. The delay time and fall time together are
called turn−on time, and, depending upon the device, will
take anywhere from tens of nanoseconds up to a few
microseconds. The propagation of conduction across the
entire junction requires a considerably longer time. The
time required for propagation or equalization of conduction is represented approximately by the time required for
the anode−to−cathode voltage to fall from the 10 percent
point to its steady state value for the particular value of
anode current under consideration (neglecting the change
due to temperature effects). It is during the interval of
time between the start of the fall of anode−to−cathode
voltage and the final equalization of conduction that the
SCR is most susceptible to damage from excessive
current.
Figure 3.13(b). Normalized Holding Current
versus Gate−to−Cathode Voltage
AVERAGE 10 DEVICES
6.0
TURN−OFF TIME (m s)
T2
NO. 4
IF = 10 A
4.0
IF = 5 A
2.0
0
0
−5.0
−10
GATE−TO−CATHODE VOLTAGE (VOLTS)
Figure 3.13(c). Turn−Off Time versus Bias
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tion is not useful, however, for determining the limitations
of the device before the entire junction is in conduction,
because they are based on measurements made with the
entire junction in conduction.
At present, there is no known technique for making a
reasonably accurate measurement of junction temperature
in the time domain of interest. Even if one were to devise
a method for switching a sufficiently large current in a
short enough time, one would still be faced with the
problem of charge storage effects in the device under test
masking the thermal effects. Because of these and other
problems, it becomes necessary to determine the device
limitations during the turn−on interval by destructive
testing. The resultant information may be published in a
form such as a maximum allowable current versus time,
or simply as a maximum allowable rate of rise of anode
current (di/dt).
Understanding the di/dt failure mechanism is part of the
problem. To the user, however, a possible cure is infinitely
more important. There are three approaches that should be
considered.
Because of the lateral base resistance the portion of the
gate closest to the gate contact is the first to be turned on
because it is the first to be forward biased. If the minimum
gate bias to cause turn−on of the device is used, the spot in
which conduction is initiated will be smallest in size. By
increasing the magnitude of the gate trigger pulse to
several times the minimum required, and applying it with
a very fast rise time, one may considerably increase the
size of the spot in which conduction starts. Figure 3.16(a)
illustrates the effect of gate drive on voltage fall time and
Figure 3.16(b) shows the improvement in instantaneous
dissipation. We may conclude from this that overdriving
the gate will improve the di/dt capabilities of the device,
and we may reduce the stress on the device by doing so.
Let us superimpose a current curve (b) on the anode−to−
cathode voltage versus time curve to better understand
this. If we allow the current to rise rapidly to a high value
we find by multiplying current and voltage that the
instantaneous dissipation curve (c) reaches a peak which
may be hundreds of times the steady state dissipation
level for the same value of current.
At the same time it is important to remember that the
dissipation does not take place in the entire junction, but
is confined at this time to a small volume. Since
temperature is related to energy per unit volume, and
since the energy put into the device at high current levels
may be very large while the volume in which it is
concentrated is very small, very high spot temperatures
may be achieved. Under such conditions, it is not difficult
to attain temperatures which are sufficient to cause
localized melting of the device.
Even if the peak energy levels are not high enough to be
destructive on a single−shot basis, it must be realized that
since the power dissipation is confined to a small area, the
power handling capabilities of the device are lessened.
For pulse service where a significant percentage of the
power per pulse is dissipated during the fall−time interval,
it is not acceptable to extrapolate the steady state power
dissipation capability on a duty cycle basis to obtain the
allowable peak pulse power.
ANODE TO CATHODE
VOLTAGE (a)
ANODE
CURRENT (b)
INSTANTANEOUS
POWER
DISSIPATION (c)
50
350
ANODE TO CATHODE VOLTAGE (VOLTS)
PERCENT OF MAXIMUM (%)
100
0
0.1
1.0
TIME (ms)
Figure 3.15. Typical Conditions — Fast−Rise, High
Current Pulse
The final criterion for the limit of operation is junction
temperature. For reliable operation the instantaneous
junction temperature must always be kept below the
maximum junction temperature as stated on the manufacturer’s data sheet. Some SCR data sheets at present
include information on how to determine the thermal
response of the junction to current pulses. This informa-
300
PEAK ANODE CURRENT = 500 A
250
200
IGT = 2 A
150
IGT = 17 mA
100
50
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
t, TIME (ms)
Figure 3.16(a). Effect of Gate Drive on Fall Time
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WHY AND HOW TO SNUB THYRISTORS
INSTANTANEOUS POWER DISSIPATION (kW)
A very straightforward approach is to simply slow down
the rate of rise of anode current to insure that it stays
within the device ratings. This may be done simply by
adding some series inductance to the circuit.
Inductive loads (motors, solenoids, etc.) present a problem
for the power triac because the current is not in phase with
the voltage. An important fact to remember is that since a
triac can conduct current in both directions, it has only a
brief interval during which the sine wave current is passing
through zero to recover and revert to its blocking state. For
inductive loads, the phase shift between voltage and current
means that at the time the current of the power handling
triac falls below the holding current and the triac ceases to
conduct, there exists a certain voltage which must appear
across the triac. If this voltage appears too rapidly, the triac
will resume conduction and control is lost. In order to
achieve control with certain inductive loads, the rate of rise
in voltage (dv/dt) must be limited by a series RC network
placed in parallel with the power triac as shown in
Figure 3.18. The capacitor CS will limit the dv/dt across the
triac.
The resistor RS is necessary to limit the surge current
from CS when the triac conducts and to damp the ringing
of the capacitance with the load inductance LL. Such an
RC network is commonly referred to as a “snubber.’’
Figure 3.19 shows current and voltage waveforms for
the power triac. Commutating dv/dt for a resistive load is
typically only 0.13 V/μs for a 240 V, 50 Hz line source
and 0.063 V/μs for a 120 V, 60 Hz line source. For
inductive loads the “turn−off’’ time and commutating dv/dt
stress are more difficult to define and are affected by a
number of variables such as back EMF of motors and the
ratio of inductance to resistance (power factor). Although
it may appear from the inductive load that the rate or rise
is extremely fast, closer circuit evaluation reveals that the
commutating dv/dt generated is restricted to some finite
value which is a function of the load reactance LL and the
device capacitance C but still may exceed the triac’s
critical commutating dv/dt rating which is about 50 V/μs.
It is generally good practice to use an RC snubber network
across the triac to limit the rate of rise (dv/dt) to a value
below the maximum allowable rating. This snubber
network not only limits the voltage rise during commutation but also suppresses transient voltages that may occur
as a result of ac line disturbances.
There are no easy methods for selecting the values for RS
and CS of a snubber network. The circuit of Figure 3.18 is a
damped, tuned circuit comprised of RS, CS, RL and LL, and
to a minor extent the junction capacitance of the triac. When
the triac ceases to conduct (this occurs every half cycle of
the line voltage when the current falls below the holding
current), the triac receives a step impulse of line voltage
which depends on the power factor of the load. A given load
fixes RL and LL; however, the circuit designer can vary RS
and CS. Commutating dV/dt can be lowered by increasing
CS while RS can be increased to decrease resonant “over
ringing’’ of the tuned circuit.
70
60
PEAK ANODE CURRENT = 500 A
50
IGT = 2 A
40
IGT = 17 mA
30
20
10
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
t, TIME (ms)
Figure 3.16(b). Effect of Gate Drive On
Turn−On Dissipation
If the application should require a rate of current rise
beyond the rated di/dt limit of the device, then another
approach may be taken. The device may be turned on to a
relatively low current level for a sufficient time for a large
part of the junction to go into conduction; then the current
level may be allowed to rise much more rapidly to very
high levels. This might be accomplished by using a delay
reactor as shown in Figure 3.17. Such a reactor would be
wound on a square loop core so that it would have sharp
saturation characteristic and allow a rapid current rise. It
is also possible to make use of a separate saturation
winding. Under these conditions, if the delay is long
enough for the entire junction to go into conduction, the
power handling capabilities of the device may be
extrapolated on a duty cycle basis.
RL
+
DELAY
REACTOR
−
SCR
Figure 3.17. Typical Circuit Use of a Delay Reactor
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1
6
2
5
BASIC CIRCUIT ANALYSIS
R
RS
Figure 3.20 shows an equivalent circuit used for
analysis, in which the triac has been replaced by an ideal
switch. When the triac is in the blocking or non−conducting state, represented by the open switch, the circuit is a
standard RLC series network driven by an ac voltage
source. The following differential equation can be
obtained by summing the voltage drops around the circuit;
AC
3
ZERO
CROSSING
CIRCUIT
CS
4
LL
RL
LOAD
Figure 3.18. Triac Driving Circuit — with Snubber
IF(ON)
(RL R S) i(t) L
IF(OFF)
AC CURRENT
COMMUTATING
dv/dt
VOLTAGE
ACROSS
POWER TRIAC
TIME
RESISTIVE LOAD
IF(ON)
IF(OFF)
dv V2 V1
t2 t1
dt
AC LINE
VOLTAGE
where V1 and t1 are the voltage and time at the 10% point
and V2 and t2 are the voltage and time at the 63% point.
Solution of the differential equation for assumed load
conditions will give the circuit designer a starting point
for selecting RS and CS.
Because the design of a snubber is contingent on the
load, it is almost impossible to simulate and test every
possible combination under actual operating conditions. It
is advisable to measure the peak amplitude and rate of rise
of voltage across the triac by use of an oscilloscope, then
make the final selection of RS and CS experimentally.
Additional comments about circuit values for SCRs and
Triacs are made in Chapter 6.
0
AC CURRENT
THROUGH
POWER TRIAC
d
COMMUTATING
dv/dt
t0
(2)
in which i(t) is the instantaneous current after the switch
opens, qc(t) is the instantaneous charge on the capacitor, VM
is the peak line voltage, and φ is the phase angle by which
the voltage leads the current prior to opening of the
switch. After differentiation and rearrangement, the equation becomes a standard second−order differential equation
with constant coefficients.
With the imposition of the boundary conditions that
i(o) = 0 and qc(o) = 0 and with selected values for RL, L,
RS and CS, the equation can be solved, generally by the
use of a computer. Having determined the magnitude
and time of occurrence of the peak voltage across the
thyristor, it is then possible to calculate the values and
times of the voltages at 10% and 63% of the peak value.
This is necessary in order to compute the dv/dt stress as
defined by the following equation:
AC LINE
VOLTAGE
t0
di(t) q c(t)
V Msin(wt f)
dt
CS
VOLTAGE
ACROSS
POWER TRIAC
TIME
INDUCTIVE LOAD
Figure 3.19. Current and Voltage Waveforms
During Commutation
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L
Figure 3.22(a) shows the construction of a sensitive
gate SCR and the path taken by leakage current flowing
out through RGK. Large SCRs (Figure 3.22(b)) keep the
path length small by bringing the gate layer up to contact
the cathode metal. This allows the current to siphon out
all−round the cathode area.
When the chip dimensions are small there is little
penalty in placing the resistor outside the package. This
gives the circuit designer considerable freedom in tailoring the electrical properties of the SCR. This is a great
advantage when low trigger or holding current is needed.
Still, there are trade−offs in the maximum allowable
junction temperature and dV/dt immunity that go with
larger resistor values. Verifying that the design is adequate
to prevent circuit upset by heat or noise is important. The
rated value for RGK is usually 1 K Ohm. Lower values
improve blocking and turn−off capability.
RL
RS
LOAD
AC
POWER
SOURCE
CS
Figure 3.20. Equivalent Circuit used for Analysis
USING SENSITIVE GATE SCRs
In applications of sensitive gate SCRs such as the ON
Semiconductor 2N6237, the gate−cathode resistor, RGK
(Figure 3.21) is an important factor. Its value affects, in
varying degrees, such parameters as IGT, VDRM, dv/dt, IH,
leakage current, and noise immunity.
DIFFUSED
CATHODE
K
K
ANODE (A)
G
P−
N
P
+
EMITTER
SHORTS
K
METAL
N
GATE (G)
G
N
N
G
N
DIFFUSED
BASE
DIFFUSED
P
N
P
ÉÉÉÉÉÉ
ÉÉÉÉÉÉ
ÉÉÉÉÉÉ ÉÉÉÉÉÉ
RGK
A
CATHODE (K)
Figure 3.21. Gate−Cathode Resistor, RGK
A
A
CASE
CASE
(a). SIMPLE
CONSTRUCTION
(b). SHORTED EMITTER
CONSTRUCTION
Figure 3.22. Sensitive Gate SCR Construction
SCR CONSTRUCTION
The sensitive gate SCR, therefore, is an all−diffused
design with no emitter shorts. It has a very high
impedance path in parallel with the gate−cathode P−N
diode; the better the process is the higher this impedance,
until a very good device cannot block voltage in the
forward direction without an external RGK. This is so,
because thermally generated leakage currents flowing
from the anode into the gate junction are sufficient to
turn on the SCR. The value for RGK is usually one
kilohm and its presence and value affects many other
parameters.
The initial step in making an SCR is the creation, by
diffusion, of P−type layers is N−type silicon base
material. Prior to the advent of the all−diffused SCR, the
next step was to form the gate−cathode P−N junction by
alloying in a gold−antimony foil. This produced a silicon
P−N junction of the regrown type over most of the junction
area. However, a resistive rather than semiconductor
junction would form where the molten alloy terminated at
the surface. This formed an internal RGK, looking in at the
gate−cathode terminals, that reduced the “sensitivity’’ of the
SCR.
Modern practice is to produce the gate−cathode junction
by masking and diffusing, a much more controllable
process. It produces a very clean junction over the entire
junction area with no unwanted resistive paths. Good
dv/dt performance by larger SCRs, however, requires
resistive paths distributed over the junction area. These
are diffused in as emitter shorts and naturally desensitize
the device. Smaller SCRs may rely on an external RGK
because the lateral resistance in the gate layer is small
enough to prevent leakage and dV/dt induced currents
from forward biasing the cathode and triggering the SCR.
FORWARD BLOCKING VOLTAGE AND
CURRENT, VDRM AND IDRM
The 2N6237 family is specified to have an IDRM, or
anode−to−cathode leakage current, of less than 200 μA at
maximum operating junction temperature and rated
VDRM. This leakage current increases if RGK is omitted
and, in fact, the device may well be able to regenerate and
turn on. Tests were run on several 2N6239 devices to
establish the dependency of the leakage current on RGK
and to determine its relationship with junction temperature, TJ, and forward voltage VAK (Figure 3.23a).
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110
Figure 3.23(a) is a plot of VAK, forward voltage, versus
RGK taken at the maximum rated operating junction
temperature of 110°C. With each device the leakage
current, IAK, is set for a VAK of 200 V, then VAK reduced
and RGK varied to re−establish the same leakage current.
The plot shows that the leakage current is not strongly
voltage dependent or, conversely, RGK may not be
increased for derate.
While the leakage current is not voltage dependent, it is
very temperature dependent. The plot in Figure 3.23(b) of
TJ, junction temperature, versus RGK taken at VDRM, the
maximum forward blocking voltage shows this dependence.
For each device (2N6329 again) the leakage current, IAK,
was measured at the maximum operating junction temperature of 110°C, then the junction temperature was reduced
and RGK varied to re−establish that same leakage current.
The plot shows that the leakage current is strongly dependent on junction temperature. Conversely RGK may be
increased for derated temperature.
A conservative rule of thumb is that leakage doubles
every 10°C. If all the current flows out through RGK,
triggering will not occur until the voltage across RGK
reaches VGT. This implies an allowed doubling of the
resistor for every 10° reduction in maximum junction
temperature. However, this rule should be applied with
caution. Static dV/dt may require a smaller resistor than
expected. Also the leakage current does not always follow
the 10° rule below 70°C because of surface effects.
To summarize, the leakage current in a sensitive gate
SCR is much more temperature sensitive than voltage
sensitive. Operation at lower junction temperatures allows
an increase in the gate−cathode resistor which makes the
SCR−resistor combination more “sensitive.’’
TJ ( °C)
90
80
70
60
1K
i
RGK
Figure 3.23(c). dv/dt Firing of an SCR
1,000V/
ms
dv/dt, RATE OF RISE OF ANODE VOLTAGE (V/m s)
VAK (VOLTS)
100 K
CAG
140
120
MCR706−6
TJ = 110°C
400 V PEAK
100V/
ms
EXPONENTIAL
METHOD
IGT = 27 mA
10V/
ms
1V/
ms 10
100
2K
50 K
dv/dt
160
1K
10 K
Figure 3.23(b). TJ versus RGK (Typical) for Constant
Leakage Current
2N6239
TJ = 110°C
IAK CONSTANT
0
5K
RGK (OHMS)
200
180
2N6239
VAK = VDRM = 200 V
IAK CONSTANT
100
IGT = 5.6 mA
100
1,000
10,000
RGK (W)
3K
Figure 3.23(d). Static dv/dt as a function of
Gate−Cathode Resistance on two devices
with different sensitivity.
RGK (OHMS)
Figure 3.23(a). VAK versus RGK (Typical) for Constant
Leakage Current
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100,000
RATE−OF−RISE OF ANODE VOLTAGE, dv/dt
GATE CURRENT, IGT(min)
An SCR’s junctions exhibit capacitance due to the
separation of charge when the device is in a blocking
state. If an SCR is subjected to forward dv/dt, this
capacitance can couple sufficient current into the SCR’s
gate to turn it on, as shown in Figure 3.23(c). RGK acts as
a diversionary path for the dv/dt current. (In larger SCRs,
where the lateral gate resistance of the device limits the
influence of RGK, this path is provided by the resistive
emitter shorts mentioned previously.) The gate−cathode
resistor, then, might be expected to have some effect on
the dv/dt performance of the SCR. Figure 3.23(d)
confirms this behavior. The static dV/dt for two MCR706
devices varies over several powers of ten with changes in
the gate−cathode resistance. Selection of the external
resistor allows the designer to trade dynamic performance
with the amount of drive current provided to the
resistor−SCR combination. The sensitive−gate device
with low RGK provides performance approaching that of
an equivalent non−sensitive SCR. This strong dependence
does not exist with conventional shorted emitter SCRs
because of their internal resistor. The conventional SCR
cannot be made more sensitive, but the sensitive−gate
device attributes can be reliably set with the resistor to
any desired point along the sensitivity range. Low values
of resistance make the dV/dt performance more uniform
and predictable. The curves for two devices with different
sensitivity diverge at high values of resistance because the
device response becomes more dependent on its sensitivity. The resistor is the most important factor determining
the static dV/dt capability of the product. Reverse biasing
the gate also improves dV/dt. A 2N6241 improved by a
factor of 50 with a 1 volt bias.
SCR manufacturers sometimes get requests for a
sensitive−gate SCR specified with an IGT(min), that is, the
maximum gate current that will not fire the device. This
requirement conflicts with the basic function of a
sensitive gate SCR, which is to fire at zero or very low
gate current, IGT(max). Production of devices with a
measurable IGT(min) is at best difficult and deliveries can
be sporadic!
One reason for an IGT(min) requirement might be some
measurable off−state gating circuit leakage current,
perhaps the collector leakage of a driving transistor. Such
current can readily be bypassed by a suitably chosen RGK.
The VGT of the SCR at the temperature in question can be
estimated from Figure 3.25, an Ohm’s Law calculation
made, and the resistor installed to define this “won’t fire’’
current. This is a repeatable design well in the control of
the equipment designer.
GATE TRIGGER VOLTAGE, VGT
The gate−cathode junction is a p−n silicon junction. So
the gate trigger voltage follows the diode law and has
roughly the same temperature coefficient as a silicon
diode, −2mV/C. Figure 3.25 is a plot of VGT versus
temperature for typical sensitive gate SCRs. They are
prone to triggering by noise coupled through the gate
circuit because of their low trigger voltage. The smallest
noise voltage margin occurs at maximum temperature and
with the most sensitive devices.
GATE CURRENT, IGT
The total gate current that a gating circuit must supply
is the sum of the current that the device itself requires to
fire and the current flowing to circuit ground through
RGK, as shown in Figure 3.24. IGT, the current required by
the device so that it may fire, is usually specified by the
device manufacturer as a maximum at some temperature
(for the 2N6236 series it is 500 μA maximum at −40°C).
The current flowing through RGK is defined by the
resistor value and by the gate−to−cathode voltage that the
SCR needs to fire. This is 1 V maximum at −40°C for the
2N6237 series, for example.
V GT , GATE TRIGGER VOLTAGE (VOLTS)
ITOT
0.9
IGT
0.8
HIGH UNIT
0.7
IGT = 200 mA @ 300°K
0.6
0.5
LOW UNIT
0.4
IGT = 20 NA @ 300°K
0.3
0.2
0.1
−30
VGT
RGK
IR
−10
10
30
50
70
90
JUNCTION TEMPERATURE (°C)
Figure 3.25. Typical VGT vs TJ
Figure 3.24. SCR and RGK “Gate’’ Currents
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110
130
1,000 Ohm resistor, between 100 μA to 1 mA of noise
current is necessary to generate enough voltage to fire the
device. Adding a capacitor sized between 0.01 and 0.1 μF
creates a noise filter and improves dV/dt by shunting
dV/dt displacement current out through the gate terminal.
These components must be placed as close as possible to
the gate and cathode terminals to prevent lead inductance
from making them ineffective. The use of the capacitor
also requires the gate drive circuit to supply enough
current to fire the SCR without excessive time delay. This
is particularly important in applications with rapidly
rising (di/dt50 A/μs) anode current where a fast rise
high amplitude gate pulse helps to prevent di/dt damage
to the SCR.
Reverse gate voltage can cause unwanted turn−off of
the SCR. Then the SCR works like a gate turn−off
thyristor. Turn−off by the gate signal is more probable
with small SCRs because of the short distance between
the cathode and gate regions. Whether turn−off occurs or
not depends on many variables. Even if turn−off does not
occur, the effect of high reverse gate current is to move
the conduction away from the gate, reducing the effective
cathode area and surge capability. Suppressing the reverse
gate voltage is particularly important when the gate pulse
duration is less than 1 microsecond. Then the part triggers by
charge instead of current so halving of the gate pulse width
requires double the gate current. Capacitance coupled
gate drive circuits differentiate the gate pulse
(Figure 3.27) leading to a reverse gate spike. The reverse
gate voltage rating should not be exceeded to prevent
avalanche damage.
This discussion has shown that the use of RGK, the
gate−cathode resistor, has many implications. Clear
understanding of its need and its influence on the
performance of the sensitive gate SCR will enable the
designer to have better control of his circuit designs using
this versatile part.
HOLDING CURRENT, IH
The holding current of an SCR is the minimum anode
current required to maintain the device in the on state. It is
usually specified as a maximum for a series of devices
(for instance, 5 mA maximum at 25°C for the 2N6237
series). A particular device will turn off somewhere
between this maximum and zero anode current and there
is perhaps a 20−to−1 spread in each lot of devices.
Figure 3.26 shows the holding current increasing with
decreasing RGK as the resistor siphons off more and more
of the regeneratively produced gate current when the
device is in the latched condition.
Note that the gate−cathode resistor determines the
holding current when it is less than 100 Ohms. SCR
sensitivity is the determining factor when the resistor
exceeds 1 meg Ohm. This allows the designer to set the
holding current over a wide range of possible values using
the resistor. Values typical of those in conventional
non−sensitive devices occur when the external resistor is
similar to their internal gate−cathode shorting resistance.
The holding current uniformity also improves when the
resistor is small.
10
I H , HOLDING CURRENT, mA
TJ = 25°C
1.0
IGT = 1.62 mA
0.1
IGT = 20 NA
0.01
0.1
1.0
10
100
1,000
RGK, GATE−CATHODE RESISTANCE, KW
Figure 3.26. 2N5064 Holding Current
NOISE IMMUNITY
Changes in electromagnetic and electrostatic fields
coupled into wires or printed circuit lines can trigger these
sensitive devices, as can logic circuit glitches. The result
is more serious than with a transistor since an SCR will
latch on. Careful wire harness design (twisted pairs and
adequate separation from high−power wiring) and printed
circuit layout (gate and return runs adjacent to one
another) can minimize potential problems. A gate cathode
network consisting of a resistor and parallel capacitor also
helps. The resistor provides a static short and is helpful
with noise signals of any frequency. For example, with a
OPTIONAL
REVERSE
GATE
SUPPRESSOR
DIODE
Figure 3.27. Capacitance Coupled Gate Drive
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DRIVERS: PROGRAMMABLE UNIJUNCTION
TRANSISTORS
voltages are reversed. Negative resistance terminology
describes the device characteristics because of the
traditional application circuit. An external reference
voltage must be maintained at the gate terminal. A typical
relaxation type oscillator circuit is shown in
Figure 3.29(a). The voltage divider shown is a typical
way of obtaining the gate reference. In this circuit, the
characteristic curve looking into the anode−cathode
terminals would appear as shown in Figure 3.29(b). The
peak and valley points are stable operating points at either
end of a negative resistance region. The peak point
voltage (VP) is essentially the same as the external gate
reference, the only difference being the gate diode drop.
Since the reference is circuit and not device dependent, it
may be varied, and in this way, VP is programmable.
In characterizing the PUT, it is convenient to speak of
the Thevenin equivalent circuit for the external gate
voltage (VS) and the equivalent gate resistance (RG). The
parameters are defined in terms of the divider resistors
(R1 and R2) and supply voltage as follows:
The programmable unijunction transistor (PUT) is a
four layer device similar to an SCR. However, gating is
with respect to the anode instead of the cathode. An
external resistive voltage divider accurately sets the
triggering voltage and allows its adjustment. The PUT
finds limited application as a phase control element and is
most often used in long duration or low battery drain timer
circuits where its high sensitivity permits the use of large
timing resistors and small capacitors. Like an SCR, the
PUT is a conductivity modulated device capable of
providing high current output pulses.
OPERATION OF THE PUT
The PUT has three terminals, an anode (A), gate (G),
and cathode (K). The symbol and a transistor equivalent
circuit are shown in Figure 3.28. As can be seen from the
equivalent circuit, the device is actually an anode−gated
SCR. This means that if the gate is made negative with
respect to the anode, the device will switch from a
blocking state to its on state.
VS R1 V1
(R1 R2)
RG R1 R2
(R1 R2)
Most device parameters are sensitive to changes in VS
and RG. For example, decreasing RG will cause peak and
valley currents to increase. This is easy to see since RG
actually shunts the device and will cause its sensitivity to
decrease.
A
ANODE
(A)
G
GATE
(G)
CHARACTERISTICS OF THE PUT
(K)
CATHODE
Figure 3.28(a).
PUT Symbol
Table 3.1 is a list of typical characteristics of ON
Semiconductor’s 2N6027/2N6028 of programmable unijunction transistors. The test circuits and test conditions
shown are essentially the same as for the data sheet
characteristics. The data presented here defines the static
curve shown in Figure 3.29(b) for a 10 V gate reference (VS)
with various gate resistances (RG). It also indicates the
leakage currents of these devices and describes the output
pulse. Values given are for 25°C unless otherwise noted.
K
Figure 3.28(b).
Transistor Equivalent
The PUT is a complementary SCR when its anode is
connected like an SCR’s cathode and the circuit bias
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PEAK POINT
VP
VS
VAK
NEGATIVE RESISTANCE REGION
RT
R2
VF
+
OUTPUT
VS
CT
VALLEY POINT
R1
−
VV
V1
IGAO
R0
IP
IV
IF
IA
Figure 3.29(a). Typical Oscillator Circuit
Figure 3.29(b). Static Characteristics
Table 3.1. Typical PUT Characteristics
Symbol
Test Circuit Figure
Test Conditions
2N6027
2N6028
Unit
IP
3.30
RG = 1 mΩ
RG = 10 kΩ
1.25
4
0.08
0.70
μA
μA
IV
3.30
RG = 1 MΩ
RG = 10 kΩ
18
150
18
150
μA
μA
VAG
(See Figure 3.31)
IGAO
VS = 40 V
(See Figure 3.32)
IGKS
VS = 40 V
5
5
nA
IF = 50 mA
0.8
0.8
V
VF
Curve Tracer Used
VO
3.33
11
11
V
tr
3.34
40
40
ns
PEAK POINT CURRENT, (IP)
current was measured with the device off just prior to
oscillation as detected by the absence of an output
voltage pulse. The 2N5270 held effect transistor circuit
is used as a current source. A variable gate voltage
supply was used to control this current.
The peak point is indicated graphically by the static
curve. Reverse anode current flows with anode voltages
less than the gate voltage (VS) because of leakage from
the bias network to the charging network. With currents
less than IP, the device is in a blocking state. With currents
above IP, the device goes through a negative resistance
region to its on state.
The charging current, or the current through a timing
resistor, must be greater than I P at VP to insure that a
device will switch from a blocking to an on state in an
oscillator circuit. For this reason, maximum values of IP
are given on the data sheet. These values are dependent
on VS temperature, and RG. Typical curves on the data
sheet indicate this dependence and must be consulted
for most applications.
The test circuit in Figure 3.30 is a sawtooth oscillator
which uses a 0.01 μF timing capacitor, a 20 V supply, an
adjustable charging current, and equal biasing resistors
(R). The two biasing resistors were chosen to given an
equivalent RG of 1 MΩ and 10 kΩ. The peak point
VALLEY POINT CURRENT, (IV)
The valley point is indicated graphically in
Figure 3.28. With currents slightly less than IV, the
device is in an unstable negative resistance state. A
voltage minimum occurs at IV and with higher currents,
the device is in a stable on state.
When the device is used as an oscillator, the charging
current or the current through a timing resistor must be
less than IV at the valley point voltage (VV). For this
reason, minimum values for IV are given on the data sheet
for RG = 10 kΩ. With RG = 1 MΩ, a reasonable “low’’ is 2
μA for all devices.
When the device is used in the latching mode, the anode
current must be greater than IV. Maximum values for IV
are given with RG = 1 MΩ. All devices have a reasonable
“high’’ of 400 μA IV with RG = 10 kΩ.
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PEAK POINT VOLTAGE, (VP)
across the PUT. A Tektronix, Type W plug−in was used to
determine this parameter.
The unique feature of the PUT is that the peak point
voltage can be determined externally. This programmable
feature gives this device the ability to function in voltage
controlled oscillators or similar applications. The triggering or peak point voltage is approximated by
FORWARD ANODE−GATE VOLTAGE, (VAG)
The forward anode−to−gate voltage drop affects the
peak point voltage as was previously discussed. The drop
is essentially the same as a small signal silicon diode and
is plotted in Figure 3.31. The voltage decreases as current
decreases, and the change in voltage with temperature is
greater at low currents. At 10 nA the temperature
coefficient is about −2.4 V/°C and it drops to about −1.6
mV/°C at 10 mA. This information is useful in
applications where it is desirable to temperature compensate the effect of this diode.
VP ≈ V T VS,
where VS is the unloaded divider voltage and VT is the
offset voltage. The actual offset voltage will always be
higher than the anode−gate voltage VAG, because IP flows
out of the gate just prior to triggering. This makes VT =
VAG + IP RG. A change in RG will affect both VAG and IP
RG but in opposite ways. First, as RG increases, IP
decreases and causes VAG to decrease. Second, since IP
does not decrease as fast as RG increases, the IP RG
product will increase and the actual VT will increase.
These second order effects are difficult to predict and
measure. Allowing VT to be 0.5 V as a first order
approximation gives sufficiently accurate results for most
applications.
The peak point voltage was tested using the circuit in
Figure 3.30 and a scope with 10 MΩ input impedance
GATE−CATHODE LEAKAGE CURRENT, (IGKS)
The gate−to−cathode leakage current is the current that
flows from the gate to the cathode with the anode shorted
to the cathode. It is actually the sum of the open circuit
gate−anode and gate−cathode leakage currents. The shorted
leakage represents current that is shunted away from the
voltage divider.
IP, IV
RS
−
+
VG
+
G
NOTES: 1) VARIOUS SENSE RESISTORS (RS) ARE USED TO
KEEP THE SENSE VOLTAGE NEAR 1 Vdc.
2) THE GATE SUPPLY (VG) IS ADJUSTED FROM
ABOUT −0.5 V TO +20 V.
S
2N5270
D
Vp
R
0.01 mF
20 V
−
OUTPUT PULSE
PUT
UNDER
TEST
R
20
R = 2 RG
VS = 10 V
Figure 3.30. Test Circuit for IP, VP and IV
GATE−ANODE LEAKAGE CURRENT, (IGAO)
FORWARD VOLTAGE, (VF)
The gate−to−anode leakage current is the current that
flows from the gate to the anode with the cathode open.
It is important in long duration timers since it adds to
the charging current flowing into the timing capacitor.
The typical leakage currents measured at 40 V are
shown in Figure 3.32. Leakage at 25°C is approximately 1 nA and the current appears to double for about
every 10°C rise in temperature.
The forward voltage (VF) is the voltage drop between
the anode and cathode when the device is biased on. It is
the sum of an offset voltage and the drop across some
internal dynamic impedance which both tend to reduce
the output pulse. The typical data sheet curve shows this
impedance to be less than 1 ohm for up to 2 A of forward
current.
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0.9
The peak output voltage is not only a function of VP, VF
and dynamic impedance, but is also affected by switching
speed. This is particularly true when small capacitors (less
than 0.01 μF) are used for timing since they lose part of
their charge during the turn on interval. The use of a
relatively large capacitor (0.2 μF) in the test circuit of
Figure 3.33 tends to minimize this last effect. The output
voltage is measured by placing a scope across the 20 ohm
resistor which is in series with the cathode lead.
0.7
VAG (VOLTS)
PEAK OUTPUT VOLTAGE, (VO)
0.5
25°C
75°C
0.3
0.1
0
0.01
RISE TIME, (tr)
1.0
0.1
10
100
1K
10 K
IAG (mA)
Figure 3.31. Voltage Drop of 2N6027 Series
Rise time is a useful parameter in pulse circuits that use
capacitive coupling. It can be used to predict the amount
of current that will flow between these circuits. Rise time
is specified using a fast scope and measuring between
0.6 V and 6 V on the leading edge of the output pulse.
70
TEMPERATURE (° C)
60
MINIMUM AND MAXIMUM FREQUENCY
In actual tests with devices whose parameters are
known, it is possible to establish minimum and maximum
values of timing resistors that will guarantee oscillation.
The circuit under discussion is a conventional RC
relaxation type oscillator.
To obtain maximum frequency, it is desirable to use low
values of capacitance (1000 pF) and to select devices and
bias conditions to obtain high IV. It is possible to use stray
capacitance but the results are generally unpredictable.
The minimum value of timing resistance is obtained using
the following rule of thumb:
50
40
30
20
1.0
10
IGAO, GATE TO ANODE LEAKAGE CURRENT (nA)
Figure 3.32. Typical Leakage Current of the 2N6027,
2N6028 Reverse Voltage Equals 40 V
R(min) 2(V 1 V V)
IV
where the valley voltage (VV) is often negligible.
To obtain minimum frequency, it is desirable to use
high values of capacitance (10 μF) and to select devices
and bias conditions to obtain low IP. It is important that
the capacitor leakage be quite low. Glass and mylar
dielectrics are often used for these applications. The
maximum timing resistor is as follows:
510 k
A
16 k
1 mF
+
20 V
−
0.2 mF
G
OUTPUT
K
R(max) (V I V P)
2IP
20
In a circuit with a fixed value of timing capacitance, our
most sensitive PUT, the 2N6028, offers the largest
dynamic frequency range. Allowing for capacitance and
bias changes, the approximate frequency range of a PUT
is from 0.003 Hz to 2.5 kHz.
27 k
V0
Figure 3.33. PUT Test Circuit for Peak Output Voltage
(Vo)
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510 k
16 k
A
V1
20 V
+
−
0.001 mF
length of the output pulse as temperature increases is
responsible for this result. Since this parameter has not
been characterized, it is obvious that temperature compensation is more practical with relatively low frequency
oscillators.
Various methods of compensation are shown in
Figure 3.36. In the low cost diode−resistor combination of
3.36(a), the diode current is kept small to cause its
temperature coefficient to increase. In 3.36(b), the bias
current through the two diodes must be large enough so
that their total coefficient compensates for VAG. The
transistor approach in 3.36(c) can be the most accurate
since its temperature coefficient can be varied independently of bias current.
TO TEKTRONICS
TYPE 567 OR
EQUIVALENT
RG = 10 k
G
1000 pF
100
K
20
27 k
100
Figure 3.34. tr Test Circuit for PUTs
100 k < R < 1 M
RT
A
+
12 V
−
1k
G
0.01 mF
K
OUTPUT
75
R
2k
(a) DIODE−RESISTOR
Figure 3.35. Uncompensated Oscillator
TEMPERATURE COMPENSATION
The PUT with its external bias network exhibits a
relatively small frequency change with temperature. The
uncompensated RC oscillator shown in Figure 3.35 was
tested at various frequencies by changing the timing
resistor RT. At discrete frequencies of 100, 200, 1000 and
2000 Hz, the ambient temperature was increased from 25°
to 60°C. At these low frequencies, the negative temperature coefficient of VAG predominated and caused a
consistent 2% increase in frequency. At 10 kHz, the
frequency remained within 1% over the same temperature
range. The storage time phenomenon which increases the
(b) DUAL−DIODE
(c) TRANSISTOR
Figure 3.36. Temperature Compensation Techniques
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SECTION 4
THE SIDAC, A NEW HIGH VOLTAGE BILATERAL TRIGGER
Edited and Updated
packages. Breakdown voltages ranging from 104 to 280 V
are available. The MKP3V devices feature bigger chips
and provide much greater surge capability along with
somewhat higher RMS current ratings.
The high-voltage and current ratings of SIDACs make
them ideal for high energy applications where other
trigger devices are unable to function alone without the
aid of additional power boosting components.
The basic SIDAC circuit and waveforms, operating off
of ac are shown in Figure 4.2. Note that once the input
voltage exceeds V(BO), the device will switch on to the
forward on-voltage VTM of typically 1.1 V and can
conduct as much as the specified repetitive peak on-state
current ITRM of 20 A (10 μs pulse, 1 kHz repetition
frequency).
The SIDAC is a high voltage bilateral trigger device
that extends the trigger capabilities to significantly higher
voltages and currents than have been previously obtainable, thus permitting new, cost-effective applications.
Being a bilateral device, it will switch from a blocking
state to a conducting state when the applied voltage of
either polarity exceeds the breakover voltage. As in other
trigger devices, (SBS, Four Layer Diode), the SIDAC
switches through a negative resistance region to the low
voltage on-state (Figure 4.1) and will remain on until the
main terminal current is interrupted or drops below the
holding current.
SIDAC’s are available in the large MKP3V series and
economical, easy to insert, small MKP1V series axial lead
ITM
SLOPE = RS
VTM
IH
IS
IDRM
VS
I(BO)
VDRM
RS V(BO)
(V(BO) VS)
(IS I(BO))
Figure 4.1(b). Actual MKP1V130 V-I Characteristic.
Horizontal: 50 V/Division. Vertical: 20 mA/Division.
(0,0) at Center. RL = 14 k Ohm.
Figure 4.1(a). Idealized SIDAC V-I Characteristics
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VIN
V(BO)
VT
V(BO)
RS RL ⎥ RS⎥
V(BO)
RL
I
VIN
IH
(V(BO) VS)
IT
IH
(IS I(BO))
CONDUCTION
θON ANGLE θOFF
RS = SIDAC SWITCHING
RESISTANCE
Figure 4.2. Basic SIDAC Circuit and Waveforms
Operation from an AC line with a resistive load can be
analyzed by superimposing a line with slope = −1/RL on
the device characteristic. When the power source is AC,
the load line can be visualized as making parallel
translations in step with the instantaneous line voltage and
frequency. This is illustrated in Figure 4.3 where v1
through v5 are the instantaneous open circuit voltages of
the AC generator and i1 through i5 are the corresponding
short circuit currents that would result if the SIDAC was
not in the circuit. When the SIDAC is inserted in the
circuit, the current that flows is determined by the
intersection of the load line with the SIDAC characteristic. Initially the SIDAC blocks, and only a small leakage
current flows at times 1 through 4. The SIDAC does not
turn-on until the load line supplies the breakover current
(I(BO)) at the breakover voltage (V(BO)).
If the load resistance is less than the SIDAC switching
resistance, the voltage across the device will drop quickly
as shown in Figure 4.2. A stable operating point (VT, IT)
will result if the load resistor and line voltage provide a
current greater than the latching value. The SIDAC
remains in an “on” condition until the generator voltage
causes the current through the device to drop below the
holding value (IH). At that time, the SIDAC switches to
the point (Voff, Ioff) and once again only a small leakage
current flows through the device.
i
i5
(VT, IT)
SLOPE I
RL
i3
i
v1, ..., v5 = INSTANTANEOUS OPEN
CIRCUIT VOLTAGES
AT TIME 1, ..., 5
(VOFF, IOFF)
RL
i1, ..., i5 = INSTANTANEOUS
SHORT CIRCUIT
CURRENTS AT
TIME 1, ..., 5
IH
RL RS
i1
(VBO, IBO)
v1 v2
v3 v4
v
v5
i v
RL
Figure 4.3. Load Line for Figure 4.2. (1/2 Cycle Shown.)
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Figure 4.4 illustrates the result of operating a SIDAC
with a resistive load greater than the magnitude of its
switching resistance. The behavior is similar to that
described in Figures 4.2 and 4.3 except that the turn-on
and turn-off of the SIDAC is neither fast nor complete.
Stable operating points on the SIDAC characteristics
between (V(BO), I(BO)) and (VS, IS) result as the
generator voltage increases from v2 to v4 . The voltage
v
I
RL
RL R S
RS = SIDAC SWITCHING RESISTANCE
across the SIDAC falls only partly as the loadline
sweeps through this region. Complete turn-on of the
SIDAC to (VT, IT) does not occur until the load line
passes through the point (VS, IS). The load line
illustrated in Figure 4.4 also results in incomplete
turn-off. When the current drops below IH, the
operating point switches to (Voff, Ioff) as shown on the
device characteristic.
(VT, IT)
i4
i3
i2
i1
IH
(VS, IS)
(VOFF, IOFF)
(VBO, IBO)
v1 v2
v3 v4
v
Figure 4.4. High Resistance Load Line with Incomplete Switching
The switching current and voltage can be 2 to 3 orders
of magnitude greater than the breakover current and
on-state voltage. These parameters are not as tightly
specified as VBO and IBO. Consequently operation of the
SIDAC in the state between fully on and fully off is
undesirable because of increased power dissipation, poor
efficiency, slow switching, and tolerances in timing.
Figure 4.5 illustrates a technique which allows the use
of the SIDAC with high impedance loads. A resistor can
be placed around the load to supply the current required to
latch the SIDAC. Highly inductive loads slow the current
rise and the turn-on of the SIDAC because of their L/R
time constant. The use of shunt resistor around the load
will improve performance when the SIDAC is used with
inductive loads such as small transformers and motors.
The SIDAC can be used in oscillator applications. If the
load line intersects the device characteristic at a point
where the total resistance (RL + RS) is negative, an
unstable operating condition with oscillation will result.
The resistive load component determines steady-state
behavior. The reactive components determine transient
behavior. Figure 4.10 shows a SIDAC relaxation oscillator application. The wide span between IBO and IH makes
the SIDAC easy to use. Long oscillation periods can be
achieved with economical capacitor sizes because of the
low device I(BO).
Z1 is typically a low impedance. Consequently the
SIDAC’s switching resistance is not important in this
application. The SIDAC will switch from a blocking to
full on-state in less than a fraction of a microsecond.
The timing resistor must supply sufficient current to fire
the SIDAC but not enough current to hold the SIDAC in
an on-state. These conditions are guaranteed when the
timing resistor is selected to be between Rmax and Rmin.
For a given time delay, capacitor size and cost is
minimized by selecting the largest allowable timing
resistor. Rmax should be determined at the lowest
temperature of operation because I(BO) increases then.
The load line corresponding to Rmax passes through the
point (V(BO), I(BO)) allowing the timing resistor to
supply the needed breakover current at the breakover
voltage. The load line for a typical circuit design should
enclose this point to prevent sticking in the off state.
Requirements for higher oscillation frequencies and
greater stored energy in the capacitor result in lower
values for the timing resistor. Rmin should be determined at the highest operating temperature because IH
is lower then. The load line determined by R and Vin
should pass below IH on the device characteristic or the
SIDAC will stick in the on-state after firing once. IH is
typically more than 2 orders of magnitude greater than
IBO. This makes the SIDAC well suited for operation
over a wide temperature span.
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conduction angle is 90° because the SIDAC must switch
on before the peak of the line voltage. Line regulation
and breakover voltage tolerances will require that a
conduction angle longer than 90° be used, in order to
prevent lamp turn-off under low line voltage conditions. Consequently, practical conduction angles will
run between 110° and 130° with corresponding power
reductions of 10% to 30%.
In Figure 4.2 and Figure 4.7, the SIDAC switching
angles are given by:
SIDAC turn-off can be aided when the load is an
under-damped oscillatory CRL circuit. In such cases,
the SIDAC current is the sum of the currents from the
timing resistor and the ringing decay from the load.
SIDAC turn-off behavior is similar to that of a TRIAC
where turn-off will not occur if the rate of current zero
crossing is high. This is a result of the stored charge
within the volume of the device. Consequently, a
SIDAC cannot be force commuted like an SCR. The
SIDAC will pass a ring wave of sufficient amplitude
and frequency. Turn-off requires the device current to
approach the holding current gradually. This is a
complex function of junction temperature, holding
current magnitude, and the current wave parameters.
RSL
L
where Vpk = Maximum Instantaneous Line Voltage
qOFF 180 SIN1
RSL RS
RL
HIGH
v
qON SIN 1 (V(BO)
V pk)
LOW
(I H RL) VT
V pk
where θON, θOFF = Switching Angles in degrees
VT = 1 V = Main Terminal Voltage at IT = IH
Generally the load current is much greater than the
SIDAC holding current. The conduction angle then
becomes 180° minus θ(on).
Rectifiers have also been used in this application to
supply half wave power to the lamp. SIDAC’s prevent the
flicker associated with half-wave operation of the lamp.
Also, full wave control prevents the introduction of a DC
component into the power line and improves the color
temperature of the light because the filament has less time
to cool during the off time.
The fast turn-on time of the SIDAC will result in the
generation of RFI which may be noticeable on AM radios
operated in the vicinity of the lamp. This can be prevented
by the use of an RFI filter. A possible filter design is
shown in Figure 4.5. This filter causes a ring wave of
current through the SIDAC at turn-on time. The filter
inductor must be selected for resonance at a frequency
above the upper frequency limit of human hearing and as
low below the start of the AM broadcast band as possible
for maximum harmonic attenuation. In addition, it is
important that the filter inductor be non-saturating to
prevent dI/dT damage to the SIDAC. For additional
information on filter design see page 92.
TYPICAL:
RSL = 2.7 k OHM
10 WATT
RS = 3 k OHM
RSL = TURN-ON SPEED
UP RESISTOR
RS = SIDAC SWITCHING
RESISTANCE
Figure 4.5. Inductive Load Phase Control
The simple SIDAC circuit can also supply switchable
load current. However, the conduction angle is not
readily controllable, being a function of the peak
applied voltage and the breakover voltage of the
SIDAC. As an example, for peak line voltage of about
170 V, at V(BO) of 115 V and a holding current of 100
mA, the conduction angle would be about 130°. With
higher peak input voltages (or lower breakdown
voltages) the conduction angle would correspondingly
increase. For non-critical conduction angle, 1 A rms
switching applications, the SIDAC is a very cost-effective device.
Figure 4.7 shows an example of a SIDAC used to
phase control an incandescent lamp. This is done in
order to lower the RMS voltage to the filament and
prolong the life of the bulb. This is particularly useful
when lamps are used in hard to reach locations such as
outdoor lighting in signs where replacement costs are
high. Bulb life span can be extended by 1.5 to 5 times
depending on the type of lamp, the amount of power
reduction to the filament, and the number of times the
lamp is switched on from a cold filament condition.
The operating cost of the lamp is also reduced
because of the lower power to the lamp; however, a
higher wattage bulb is required for the same lumen
output. The maximum possible energy reduction is 50%
if the lamp wattage is not increased. The minimum
ZL
VIN
SIDAC
Figure 4.6. SIDAC Circuit
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100 WATT
240 V
220 VAC
100 μHY PREM SPE304
RDC = 0.04 Ω
0.1 μF
OPTIONAL
RFI FILTER
(2)MKP1V130RL
400 V
Figure 4.7. Long-Life Circuit for Incandescent Lamp
The sizing of the SIDAC must take into account the
RMS current of the lamp, thermal properties of the
SIDAC, and the cold start surge current of the lamp which
is often 10 to 20 times the steady state load current.
When lamps burn out, at the end of their operating life,
very high surge currents which could damage the SIDAC
are possible because of arcing within the bulb. The large
MKP3V device is recommended if the SIDAC is not to be
replaced along with the bulb.
Since the MKP3V series of SIDACs have relatively
tight V(BO) tolerances (104 V to 115 V for the − 115
device), other possible applications are over-voltage
protection (OVP) and detection circuits. An example of
this, as illustrated in Figure 4.8, is the SIDAC as a
transient protector in the transformer-secondary of the
medium voltage power supply, replacing the two more
expensive back-to-back zeners or an MOV. The device
can also be used across the output of the regulator
(100 V) as a simple OVP, but for this application, the
regulator must have current foldback or a circuit breaker
(or fuse) to minimize the dissipation of the SIDAC.
Another example of OVP is the telephony applications
as illustrated in Figure 4.9. To protect the Subscriber Loop
Interface Circuit (SLIC) and its associated electronics
from voltage surges, two SIDACs and two rectifiers are
used for secondary protection (primary protection to
1,000 V is provided by the gas discharge tube across the
lines). As an example, if a high positive voltage transient
appeared on the lines, rectifier D1 (with a P.I.V. of 1,000
V) would block it and SIDAC D4 would conduct the surge
to ground. Conversely, rectifier D2 and SIDAC D3 would
protect the SLIC for negative transients. The SIDACs will
not conduct when normal signals are present.
Being a negative resistance device, the SIDAC also
can be used in a simple relaxation oscillator where the
frequency is determined primarily by the RC time
constant (Figure 4.10). Once the capacitor voltage
reaches the SIDAC breakover voltage, the device will
fire, dumping the charged capacitor. By placing the
load in the discharge path, power control can be
obtained; a typical load could be a transformer-coupled
xeon flasher, as shown in Figure 4.12.
SIDAC AS A TRANSIENT
PROTECTOR
SIDAC AS AN
OVP
VO 100 V
REG.
VIN
z
Figure 4.8. Typical Application of SIDACs as a Transient Protector and OVP in a Regulated Power Supply
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MOC3031
90 V RMS @ −48 Vdc
RING GENERATOR
RING ENABLE
0 TO + 5 V
RE
GND
RG1
105 V
135 V
RG2
TIP
RPT
1N4007
RT
D1
TIP
DRIVE
TIP
SENSE
RR
RPR
RING
RING
SENSE
1N4007
PRIMARY
PROTECTION
GAS DISCHARGE
TUBE
SLIC
MC3419-1L
RING
DRIVE
D2
SECONDARY
PROTECTION
−48 V
BATTERY
Figure 4.9. SIDACs Used for OVP in Telephony Applications
V(BO)
R
VIN V(BO)
VC
VC
t
iL
C
ZL
iL
t
RMAX RMIN t
V IN V (BO)
I
t RC In
VBO
I
VIN I(BO)
VIN VTM
IH
Figure 4.10. Relaxation Oscillator Using a SIDAC
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SIDAC’s provide an economical means for starting high
intensity high pressure gas discharge lamps. These lamps
are attractive because of their long operating life and high
efficiency. They are widely used in outdoor lighting for
these reasons.
Figure 4.13 illustrates how SIDAC’s can be used in
sodium vapor lamp starters. In these circuits, the SIDAC
is used to generate a short duration (1 to 20 μs)
high-voltage pulse of several KV or more which is timed
by means of the RC network across the line to occur near
the peak of the AC input line voltage. The high voltage
pulse strikes the arc which lights the lamp.
In these circuits, an inductive ballast is required to
provide a stable operating point for the lamp. The lamp is
a negative resistance device whose impedance changes
with current, temperature, and time over the first few
minutes of operation. Initially, before the lamp begins to
conduct, the lamp impedance is high and the full line
voltage appears across it. This allows C to charge to the
breakover voltage of the SIDAC, which then turns on
discharging the capacitor through a step-up transformer
generating the high voltage pulse. When the arc strikes,
the voltage across the lamp falls reducing the available
charging voltage across RC to the point where VC no
longer exceeds V(BO) and the SIDAC remains off. The
low duty cycle lowers average junction temperature
improving SIDAC reliability. Normal operation approximates non-repetitive conditions. However, if the lamp
fails or is removed during replacement, operation of the
SIDAC will be at the 60 Hz line frequency. The design of
the circuit should take into account the resulting steady
state power dissipation.
LB
R
C1
vac
C
(a). Conventional HV Transformer
LB
C
vac
R
(b). H.V. Auto-Transformer
LB
C
vac
R
VIN
HV
(c). Tapped Ballast Auto Transformer
Figure 4.13. Sodium Vapor Lamp Starter Circuits
Figure 4.11. Typical Capacitor Discharge SIDAC Circuit
220
2W
VIN ≈
300 V
+
1M
2W
20 μF
400 V
560 k
2W
1 μF
200 V
125 V
Figure 4.14 illustrates a solid state fluorescent lamp
starter using the SIDAC. In this circuit the ballast is
identical to that used with the conventional glow-tube
starter shown in Figure 4.15.
The glow tube starter consists of a bimetallic switch
placed in series with the tube filaments which closes to
energize the filaments and then opens to interrupt the
current flowing through the ballast inductor thereby
generating the high-voltage pulse necessary for starting.
The mechanical glow-tube starter is the circuit component
most likely to cause unreliable starting.
2 kW
XEON TUBE
RS-272-1145
+
4 kV PULSE TRANSFORMER
RS-272-1146
Figure 4.12. Xeon Flasher Using a SIDAC
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LB
size of C determines the amount of filament heating
current by setting the impedance in the filament circuit
before ionization of the tube.
The evolution of this circuit can be understood by first
considering an impractical circuit (Figure 4.16).
If LB and C are adjusted for resonance near 60 Hz, the
application of the AC line voltage will result in a charging
current that heats the filaments and a voltage across the
capacitor and tube that grows with each half-cycle of the
AC line until the tube ionizes. Unfortunately, C is a large
capacitor which can suddenly discharge through the tube
causing high current pulses capable of destroying the tube
filament. Also C provides a permanent path for filament
current after starting. These factors cause short tube
operating life and poor efficiency because of filament
power losses. The impractical circuit must be modified to:
(1) Switch off the filament current after starting.
(2) Limit capacitor discharge current spikes.
In Figure 4.14 a parallel connected rectifier and SIDAC
have been added in series with the capacitor C. The
breakover voltage of the SIDAC is higher than the peak of
the line voltage. Diode D1 is therefore necessary to
provide a current path for charging C.
On the first half-cycle, C resonant charges through
diode D1 to a peak voltage of about 210 V, and remains at
that value because of the blocking action of the rectifier
and SIDAC. During this time, the bleeder resistor R has
negligible effect on the voltage across C because the RC
time constant is long in comparison to the line period.
When the line reverses, the capacitor voltage boosts the
voltage across the SIDAC until breakover results. This
results in a sudden step of voltage across the inductor L,
causing resonant charging of the capacitor to a higher
voltage on the 2nd half-cycle.
D1
SYLVANIA
F15T8/CW
D2
115 VAC
R
PTC
L
LB
UNIVERSAL MFG CORP CAT200-H2
14-15-20-22 WATT BALLAST
325 mHY 28.9 Ω DCR
D1
1N4005 RECTIFIER
D2
(2) MKP1V130RL SIDAC
C
3 VFD 400 V
R
68 k OHMS 112 WATT
PTC
KEYSTONE CARBON COMPANY
RL3006-50-40-25-PTO
50 OHMS/25°C
L
MICROTRAN QIL 50-F
50 mHY 11 OHMS
Figure 4.14. Fluorescent Starter Using SIDAC
The heating of the filaments causes thermonic emission
of electrons from them. These electrons are accelerated
along the length of the tube causing ionization of the
argon gas within the tube. The heat generated by the
starting current flow through the tube vaporizes the
mercury droplets within the tube which then become
ionized themselves causing the resistance and voltage
across the tube to drop significantly. The drop in voltage
across the tube is used to turn off the starting circuit and
prevent filament current after the lamp is lit.
The SIDAC can be used to construct a reliable starter
circuit providing fast, positive lamp ignition. The starter
shown in Figure 4.14 generates high voltage by means of
a series CRL charging circuit. The circuit is roughly
analogous to a TRIAC snubber used with an inductive
load, except for a lower damping factor and higher Q. The
NEON GAS
FLUORESCENT
COATING
COATED
FILAMENT
STARTER
(ARGON GAS)
MERCURY DROPLETS
BALLAST
INDUCTOR
VAC
Figure 4.15. Fluorescent Lamp with Glow Tube Starter
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BALLAST
CHOKE
fo RB
1
60 Hz
2a LC
LB
V
C
VAC
Q
XLB
RTOTAL
−V START
Vmax Q VAC 2
VSTART VMAX
Figure 4.16. Impractical Starter Circuit
(a). 5 ms/DIVISION
(b). 100 ms/DIVISION
Figure 4.17. Starting Voltage Across Fluorescent Tube 100 V/DIV
0 V AT CENTER
VLine = 110 V
Several cycles of operation are necessary to approach
steady state operating conditions. Figure 4.17 shows the
starting voltage waveform across the tube.
The components R, PTC, and L serve the dual role of
guarantying SIDAC turn-off and preventing capacitor
discharge currents through the tube.
SIDAC’s can also be used with auto-transformer ballasts.
The high voltage necessary for starting is generated by the
leakage autotransformer. The SIDAC is used to turn-on the
filament transformer initially and turn it off after ionization
causes the voltage across the tube to drop.
Figure 4.18 illustrates this concept. The resistor R can
be added to aid turn-off of the SIDAC by providing a
small idle current resulting in a voltage drop across the
impedance Z. The impedance Z could be a saturable
reactor and or positive temperature coefficient thermistor.
These components help to insure stability of the system
comprised of the negative resistance SIDAC and negative
resistance tube during starting, and promote turn off of the
SIDAC.
The techniques illustrated in Figure 4.13 are also
possible methods for generation of the necessary highvoltage required in fluorescent starting. The circuits must
be modified to allow heating of the fluorescent tube
cathodes if starting is to simulate the conditions existing
when a glow tube is used.
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C
VBO VSTART
VBO VOPERATING
Z
V
VAC
R
Figure 4.18. Fluorescent Starter Using SIDAC and Autotransformer Ballast
tion then becomes; how much “real world” surge current
can the SIDAC sustain? The data sheet defines an ITSM of
20 A, but this is for a 60 Hz, one cycle, peak sine wave
whereas the capacitor discharge current waveform has a
fast-rise time with an exponential fall time.
To generate the surge current curve of peak current
versus exponential discharge pulse width, the test circuit
of Figure 4.19 was implemented. It simulates the topology
of many applications whereby a charged capacitor is
dumped by means of a turned-on SIDAC to produce a
current pulse. Timing for this circuit is derived from the
nonsymmetrical CMOS astable multivibrator (M.V.) gates
G1 and G2. With the component values shown, an
approximate 20 second positive-going output pulse is fed
to the base of the NPN small-signal high voltage transistor
Q1, turning it on. The following high voltage PNP
transistor is consequently turned on, allowing capacitor
C1 to be charged through limiting resistor R1 in about 16
seconds. The astable M.V. then changes state for about 1.5
seconds with the positive going pulse from Gate 1 fed
through integrator R2-C2 to Gate 3 and then Gate 4. The
net result of about a 100 μs time delay from G4 is to
ensure non-coincident timing conditions. This positive
going output is then differentiated by C3-R3 to produce an
approximate 1 ms, leading edge, positive going pulse
which turns on NPN transistor Q3 and the following PNP
transistor Q4. Thus, an approximate 15 mA, 1 ms pulse is
generated for turning on SCR Q5 about 100 μs after
capacitor charging transistor Q2 is turned off. The SCR
now fires, discharging C1 through the current limiting
resistor R4 and the SIDAC Device Under Test (D.U.T.).
The peak current and its duration is set by the voltage VC
across capacitor C1 and current limiting resistor R4. The
circuit has about a 240 V capability limited by C1, Q1 and
Q2 (250 V, 300 V and 300 V respectively).
Table 4.1. Possible Sources for Thermistor Devices
Fenwal Electronics, 63 Fountain Street
Framingham MA 01701
Keystone Carbon Company, Thermistor Division
St. Marys, PA 15857
Thermometrics, 808 U.S. Highway 1
Edison, N.J. 08817
Therm-O-Disc, Inc. Micro Devices Product Group
1320 South Main Street, Mansfield, OH 44907
Midwest Components Inc., P.O Box 787
1981 Port City Boulevard, Muskegon, MI 49443
Nichicon (America) Corp., Dept. G
927 E. State Pkwy, Schaumburg, IL 60195
Thermistors are useful in delaying the turn-on or
insuring the turn-off of SIDAC devices. Table 4.1 shows
possible sources of thermistor devices.
Other high voltage nominal current trigger applications
are:
• Gas or oil igniters
• Electric fences
• HV electrostatic air filters
• Capacitor Discharge ignitions
Note that all these applications use similar circuits
where a charged capacitor is dumped to generate a high
transformer secondary voltage (Figure 4.11).
In many cases, the SIDAC current wave can be approximated by an exponential or quasi-exponential current
wave (such as that resulting from a critically damped or
slightly underdamped CRL discharge circuit). The ques-
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58
+15 V
R2
100 k
+15 V
1
3
G3
2
C2
5
4
G4
6
0.001 μF
MC14011
VCC 240 V
10 k
+15 V
+15 V
39 k
2W
14
8
G1
12
G2
13
9
22 M
10
22 M
11
47 k
7
2.2 M
1N914
22 k
Q1
MPS
A42
Q2
MJ4646
R1
4k
5W
+15 V
SIDAC
DUT
LED
R4
C1
80 μF
250 V
3.3 Ω
2W
0.47 μF
10 k
2N3906
Q4
1k
Q5
MCR
6507
1k
C3
0.1 μF
R3
10 k
1N
4003
Q3
2N3904
10 k
22 k
1N914
Figure 4.19. SIDAC Surge Tester
100
I pk, SURGE CURRENT (AMPS)
The SCR is required to fire the SIDAC, rather than the
breakover voltage, so that the energy to the D.U.T. can be
predictably controlled.
By varying VC, C1 and R4, the surge current curve of
Figure 4.20 was derived. Extensive life testing and
adequate derating ensure that the SIDAC, when properly
used, will reliably operate in the various applications.
30
Ipk
10
10%
tw
3
1
0.3
1
3
10
tw, PULSE WIDTH (ms)
30
100
300
Figure 4.20. Exponential Surge Current Capability of
the MKP3V SIDAC. Pulse Width versus Peak Current
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SECTION 5
SCR CHARACTERISTICS
Edited and Updated
is necessary to apply a negative (reverse) voltage to the
device anode, causing the holes and electrons near the two
end junctions, J1 and J3, to diffuse to these junctions. This
causes a reverse current to flow through the SCR. When
the holes and electrons near junctions J1 and J3 have been
removed, the reverse current will cease and junctions J1
and J3 will assume a blocking state. However, this does
not complete the recovery of the SCR since a high
concentration of holes and electrons still exist near the
center junction, J2. This concentration decreases by the
recombination process and is largely independent of the
external circuit. When the hole and electron concentration
near junction J2 has reached some low value, junction J2
will assume its blocking condition and a forward voltage
can, after this time, be applied without the SCR switching
back to the conduction state.
SCR TURN−OFF CHARACTERISTICS
In addition to their traditional role of power control
devices, SCRs are being used in a wide variety of other
applications in which the SCR’s turn−off characteristics are
important. As in example — reliable high frequency
inverters and converter designs (20 kHz) require a known
and controlled circuit−commutated turn−off time (tq). Unfortunately, it is usually difficult to find the turn−off time of a
particular SCR for a given set of circuit conditions.
This section discusses tq in general and describes a
circuit capable of measuring tq. Moreover, it provides data
and curves that illustrate the effect on tq when other
parameters are varied, to optimize circuit performance.
SCR TURN−OFF MECHANISM
ANODE
The SCR, being a four layer device (P−N−P−N), is
represented by the two interconnected transistors, as
shown in Figure 5.1. This regenerative configuration
allows the device to turn on and remain on when the gate
trigger is removed, as long as the loop gain criteria is
satisfied; i.e., when the sum of the common base current
gains (α) of both the equivalent NPN transistor and PNP
transistor, exceed one. To turn off the SCR, the loop gain
must be brought below unity, whereby the on−state
principal current (anode current iT) limited by the external
circuit impedance, is reduced below the holding current
(IH). For ac line applications, this occurs automatically
during the negative going portion of the waveform.
However, for dc applications (inverters, as an example),
the anode current must be interrupted or diverted;
(diversion of the anode current is the technique used in the
tq test fixture described later in this application note).
ANODE
P
J1
N
GATE
J2
P
J3
N
GATE
CATHODE
CATHODE
P−N−P−N STRUCTURE
ANODE
ANODE
ITM
Q1
IB1 = IC2
P
SCR TURN−OFF TIME tq
Once the anode current in the SCR ceases, a period of
time must elapse before the SCR can again block a
forward voltage. This period is the SCR’s turn−off time,
tq, and is dependent on temperature, forward current, and
other parameters. The turn−off time phenomenon can be
understood by considering the three junctions that make
up the SCR. When the SCR is in the conducting state,
each of the three junctions is forward biased and the N and
P regions (base regions) on either side of J2 are heavily
saturated with holes and electrons (stored charge). In
order to turn off the SCR in a minimum amount of time, it
N
N
IC1 = IB2
P
P
GATE
Q2
N
GATE
CATHODE
CATHODE
TWO TRANSISTOR MODEL
Figure 5.1. Two Transistor Analogy of an SCR
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60
tq MEASUREMENT
Synchronized Pulse Generator establishes system timing;
a Constant Current Generator (variable in amplitude)
powers the Device Under Test (DUT); a di/dt Circuit
controls the rate of change of the SCR turn−off current;
and the dv/dt Circuit reapplies a controlled forward
blocking voltage. Note from the waveforms illustrated
that the di/dt circuit, in parallel with the DUT, diverts the
constant current from the DUT to produce the described
anode current ITM.
When measuring SCR turn−off time, tq, it is first
necessary to establish a forward current for a period of
time long enough to ensure carrier equilibrium. This must
be specified, since ITM has a strong effect on the turn−off
time of the device. Then, the SCR current is reversed at a
specified di/dt rate, usually by shunting the SCR anode to
some negative voltage through an inductor. The SCR will
then display a “reverse recovery current,” which is the
charge clearing away from the junctions. A further
waiting time must then elapse while charges recombine,
before a forward voltage can be applied. This forward
voltage is ramped up a specified dv/dt rate. The dv/dt
delay time is reduced until a critical point is reached
where the SCR can no longer block the forward applied
voltage ramp. In effect, the SCR turns on and consequently, the ramp voltage collapses. The elapsed time
between this critical point and the point at which the
forward SCR current passes through zero and starts to go
negative (reverse recovery phase), is the tq of the SCR.
This is illustrated by the waveforms shown in Figure 5.2.
tq TEST FIXTURE CHARACTERISTICS
The complete schematic of the tq Test Fixture and the
important waveforms are shown in Figures 5.5 and 5.6,
respectively.
A CMOS Gate is used as the Line Synchronized Pulse
Generator, configured as a wave shaping Schmitt trigger,
clocking two cascaded monostable multivibrators for delay
and pulse width settings (Gates 1C to 1F). The result is a
pulse generated every half cycle whose width and position
(where on the cycle it triggers) are adjustable by means of
potentiometers R2 and R3, respectively. The output pulse is
normally set to straddle the peak of the ac line, which not
only makes the power supplies more efficient, but also
allows a more consistent oscilloscope display. This pulse
shown in waveform A of Figure 5.6 initiates the tq test,
which requires approximately 0.5 ms to assure the device a
complete turn on. A fairly low duty cycle results, (approximately 5%) which is important in minimizing temperature
effects. The repetitive nature of this test permits easy oscilloscope viewing and allows one to readily “walk in” the dv/dt
ramp. This is accomplished by adjusting the appropriate
potentiometer (R7) which, every 8.33 ms (every half cycle)
will apply the dv/dt ramp at a controlled time delay.
tq GENERAL TEST FIXTURE
The simplified circuit for generating these waveforms is
schematically illustrated in Figure 5.3. This circuit is
implemented with as many as eight transformers including variacs, and in addition to being very bulky, has been
known to be troublesome to operate. However, the
configuration is relevent and, in fact, is the basis for the
design, as described in the following paragraphs.
tq TEST FIXTURE BLOCK DIAGRAMS AND WAVEFORMS
The block diagram of the tq Test Fixture, illustrated in
Figure 5.4, consists of four basic blocks: A Line
di/dt
ITM
50% ITM
IDX
50% IRM
IRM
trr
VDX
tq
dv/dt
VT
Figure 5.2. SCR Current and Voltage Waveforms During Circuit−Commutated Turn−Off
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S2
S3
IT
L1
R2
D1
D2
S1
IT
dv/dt
di/dt
D3
I1
V2
S4
DUT
C1
V1
R1
V3
Figure 5.3. Simplified tq Test Circuit
To generate the appropriate system timing delays, four
RC integrating network/comparators are used, consisting
of op−amps U2, U5 and U6.
Op−amp U2A, along with transistor Q2, opto−coupler U4
and the following transistors Q6 and Q7, provide the gate
drive pulse to the DUT (see waveforms B, C and D of
Figure 5.6). The resulting gate current pulse is about 50 μs
wide and can be selected, by means of switch S2, for an IGT
of from about 1 mA to 90 mA. Opto−coupler U4, as well as
U1 in the Constant Current Circuit, provide electrical
isolation between the power circuitry and the low level
circuitry.
The Constant Current Circuit consists of an NPN Darlington Q3, connected as a constant current source driving a
PNP tri−Darlington (Darlington Q4, Bipolar Q5). By varying the base voltage of Q3 (with Current Control potentiometer R4), the collector current of Q3 and thus the base
voltage of Q4 will also vary. The PNP output transistor Q5
(MJ14003) (rated at 70 A), is also configured as a constant
current source with four, parallel connected emitter resistors
(approximately 0.04 ohms, 200 W), thus providing as much
as 60 A test current. Very briefly, the circuit operates as
follows: — CMOS Gate 1E is clocked high, turning on, in
order, a) NPN transistor Q16, b) PNP transistor Q1, c)
optocoupler U3, and d) transistors Q3, Q4 and Q5. The
board mounted Current Set potentiometer R5, sets the
maximum output current and R4, the Current Control, is a
front panel, multiturn potentiometer.
CONSTANT
CURRENT
GENERATOR
D1
DUT
LINE SYNC
PULSE
GENERATOR
IT
dv CIRCUIT
dt
di CIRCUIT
dt
IGT
CONSTANT
CURRENT
di/dt
IT
di/dt
0
V1
dv/dt
dv/dt
Figure 5.4. Block Diagram of the tq Test Fixture
and Waveforms
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62
LINE SYNCHRONIZED PULSE GENERATOR
+ 10 V
+ 10 V
1k
1N914
220 k
22 k
2
1 4
1A
10 k
TRIAD
F93X
120 V
SWD
2000
μF
−V1
−18 V
TYP
+ 10 V
16
1B
8 3
220 pF
1M
0.01
μF
6
100 k
5
7
3 LM317T
U7
25 V 1
+ 10 V
2
+
50 μF
20 V
240
25 k R3
PULSE WIDTH
CONTROL
1k
1.5 k
Q1
2N
3906
+
1/2 W 1 k
−5 V
10 V
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63
1N4733
5.1 V, 1 W
330
1W
10 k
0.1
μF
100 μF
+ 20 V
1N
914
510 k
10 k
12 k + 10 V
1N4740
10 V, 1 W
+
3
2 U2A
820 pF
2
Q2
(1/2)
MC1458
2N3904
1
L1:
D1 :
I1 :
CURRENT
CONTROL
R4
1k
CURRENT
SET
R5
+ 10 V
5
1k
C1 :
DETERMINED BY SPEC dv/dt
− V2 :
− 12 V (TYP), − 50 V
GATE CURRENT
SW S2
1N
5370A
1.2 K
56 V
2W
5W
− V2 o
Q11
82 90 mA
IT
DUT
330 30
o
1W
820 10
150
160 50
1N
5932A
0.001
μF
I1
150 k
V
2N3904
+ 10 V
8.2 k 1 mA
SW.53
OFF
+ 10 V BIAS
3.3 k
4.7 k
U6
MC1741
150 k, 10 T 1 k
VREF
0.1
μF
50 k
0.02
μF
R6
ON TIME
CONTROL
5 +
6 U2B
−
0.001 μF
tq TIME
CONTROL R7
7
(1/2)
MC1458
− 10 V
39 k
0.002
μF
Figure 5.5. tq Test Fixture
1k
2W
1N
4747
2N3904
Q13
− 10 V
− V1
− 18 V
MJE
250
Q14
+ 10 V
0.1 μF
5 8
+
7
6 −U5
4 (1/2)
MC1458
U5
0.001 μF
MJE254
Q9
56
2W
1k
1N4728
0.1
μF
10 k
1k
1N4728
7
1.8 k
6
+
2 U6
− 4
10 k
3.3 V
0.1 μF
+ 10 V
470
MTM2N90
Q15
C1
+ 10 V
3
0.001
μF
1K
2W
+ V1
o
R1
560
2W
0.002 1N
μF 5932A
1N
5932A
20 V
1.5 W
A
−5V
0.1 μF
Q12
.001
μF
1000
1k
560
2W
1K
2W
MR856
120 70
10 k
di
CIRCUIT
dt
560
2W
Q6
V1
V1
50V
(TYP)
R 1 50
100
1W
D1
2N
4919
Q7
20
1k
≈ 50 mA FOR HIGH tq DUTS
≈ 1 A FOR LOW tq
− V1
+ 10 V
4
2
MR506 FOR 3 A, HIGH tq DUTS
MR856 FOR 3 A, LOW tq DUTS
(DIODE IF SCALED TO DUT IA)
50V
(TYP)
R 1 1k
100
1W
1k
Q10
100 k
MPS
A13
120 V
60 Hz
STANCOR
P6337
(3) MTM15N06E
*
1k
4N35
U4
0 μH (TYP)
*DIODE REQUIRED WITH L1
L1
Q3
4
50,000
μF
25 V
MJ
14003
Q5
100
1/2 W
3.3 V
−
47
2W
100
1W
5
4N35
U3
0.1 μF
1N4728 3.3 k
2N6042
Q4
+ 10 V
430
2W
SW S1
0.1 μF, 200 V
+
1.2 k
2W
0.1
μF
POWER ON
0.1 μF
200 V
(4) 0.15 Ω, 50 W
CONSTANT
CURRENT
CIRCUIT
− 10 V
2 A S.B.
+ 20 V (UNLOADED)
+ 12 V (LOADED)
47 k
2N3904
Q16
1.8 k
20,000
μF 25 V
150 k 100 k
15
0.1 μF
11
12
9
1E
1F
1D
14
10
13
0.001
4.7 k
μF
1C
+ 10 V
1N4001
+
R2
PULSE
DELAY + 10 V
CONTROL
U1
MC14572
100
470
dv
CIRCUIT
dt
10 μF
15 V
+
10 k
1N
914
10 k
o
2N4401
SYNC
Q8
OUT
Time delay for the di/dt Circuit is derived from
cascaded op−amps U2B and U5 (waveforms F and G of
Figure 5.6). The output gate, in turn, drives NPN
transistor Q8, followed by PNP transistor Q9, whose
output provides the gate drive for the three parallel
connected N−channel power MOSFET transistors
Q10 −Q12 (waveforms H of Figure 5.6). These three
FETs (MTM15N06), are rated at 15 A continuous drain
current and 40 A pulsed current and thus can readily
divert the maximum 60 A constant current that the
Fixture can generate. The results of this diversion from
the DUT is described by waveforms E, H and I of
Figure 5.6, with the di/dt of of ITM dictated by the series
inductance L1. For all subsequent testing, the inductor
was a shorting bar, resulting in very little inductance
and consequently, the highest di/dt (limited primarily
by wiring inductance). When a physical inductor L1 is
used, a clamp diode, scaled to the diverted current,
should be placed across L1 to limit “inductive kicks.”
shown in Figure 5.7 where both a fast recovery rectifier
and standard recovery rectifier were used in measuring tq
of a standard 2N6508 SCR. Although the di/dt’s were the
same, the reverse recovery current IRM and trr were
greater with the standard recovery rectifier, resulting in a
somewhat shorter tq (59 μs versus 63 μs). In fact, tq is
affected by the initial conditions (ITM, di/dt, IRM, dv/dt,
etc.) and these conditions should be specified to maintain
measurement repeatability. This is later described in the
published curves and tables.
Finally, the resistor R1 and the resultant current I1 in the
dv/dt circuit must meet certain criteria: I1 should be
greater than the SCR holding current so that when the
DUT does indicate tq limitation, it latches up, thus
suppressing the dv/dt ramp voltage; and, for fast SCRs
(low tq), I1 should be large enough to ensure measurement
repeatability. Typical values of I1 for standard and fast
SCRs may be 50 mA and 500 mA, respectively.
Obviously, for high forward blocking voltage + V1 tests,
the power requirements must be met.
dv/dt CIRCUIT
EFFECTS OF GATE BIAS ON tq
The last major portion of the Fixture, the dv/dt Circuit,
is variable time delayed by the multi−turn, front panel tq
Time Control potentiometer R7, operating as part of an
integrator on the input of comparator U6. Its output
(waveform J of Figure 5.6) is used to turn−off, in order, a)
normally on NPN transistor Q13, b) PNP transistor Q14
and c) N−channel power MOSFET Q15 (waveform L of
Figure 5.6). This FET is placed across ramp generating
capacitor C1, and when unclamped (turned off), the
capacitor is allowed to charge through resistor R1 to the
supply voltage +V1. Thus, the voltage appearing on the
drain will be an exponentially rising voltage with a dv/dt
dictated by R1, C1, whose position in time can be
advanced or delayed. This waveform is then applied
through a blocking diode to the anode of the DUT for the
forward blocking voltage test.
Another blocking diode, D1, also plays an important
role in tq measurements and must be properly selected. Its
purpose is to prevent the dv/dt ramp from feeding back
into the Current Source and di/dt Circuit and also to
momentarily apply a reverse blocking voltage (a function
of −V2 of the di/dt circuit) to the DUT. Consequently, D1
must have a reverse recovery time trr greater than the
DUT, but less than the tq time. When measuring standard
recovery SCRs, its selection — fast recovery rectifiers or
standard recovery — is not that critical, however, for fast
recovery, low tq SCRs, the diode must be tailored to the
DUT to produce accurate results. Also, the current rating
of the diode must be compatible with the DUT test
current. These effects are illustrated in the waveforms
Examples of the effects of I1 on tq are listed in
Table 5.III whereby standard and fast SCRs were tested
with about 50 mA and 1 A, respectively. Note that the low
tq SCR’s required fast recovery diodes and high I1 current.
TEST FIXTURE POWER SUPPLIES
Most of the power supplies for the system are self
contained, including the +12 V supply for the Constant
Current Circuit. This simple, unregulated supply furnishes
up to 60 A peak pulsed current, primarily due to the line
synchronized operation of the system. Power supplies
+ V1 and −V2, for this exercise, were external supplies,
since they are variable, but they can be incorporated in the
system. The reverse blocking voltage to the DUT is
supplied by − V2 and is typically set for about −10 V to
−20 V, being limited to the breakdown voltage of the
diverting power MOSFETS (VDSS = 60 V). The +12 V
unregulated supply can be as high as +20 V when
unloaded; therefore, −V2 (MAX), in theory, would be
−40 V but should be limited to less than −36 V due to the
56 V protective Zener across the drain−source of the
FETs. Also, −V2 must be capable of handling the peak
60 A, diverting current, if so required.
The reapplied forward blocking voltage power supply
+ V1, may be as high as the DUT VDRM which
conceivably can be 600 V, 1,000 V or greater and, since
this supply is on most of the time, must be able to supply
the required I1. Due to the sometimes high power
requirements, +V1 test conditions may have to be reduced
for extremely fast SCRs.
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PARAMETERS AFFECTING tq
densed and shown in Table 5.1. The data consists of the
different conditions which the particular SCR types
were subjected to; ten SCRs of each type were
serialized and tested to each condition and the ten tq ’s
were averaged to yield a “typical tq .”
The conditions listed in Column A in Table 5.1, are
typical conditions that might be found in circuit operation. Columns B through J in Table 5.1, are in order of
increasing tq; the conditions listed in these columns are
only the conditions that were modified from those in
Column A and if a parameter is not listed, it is the same as
in Column A.
To see how the various circuit parameters can affect tq,
one condition at a time is varied while the others are held
constant. The parameters to be investigated are a) forward
current magnitude (ITM), b) forward current duration,
c) rate of change of turn−off current (di/dt), d) reverse−
current magnitude (IRM), e) reverse voltage (VRM), f) rate
of reapplied forward voltage (dv/dt), g) magnitude limit
of reapplied voltage, h) gate−cathode resistance and
i) gate drive magnitude (IGT).
Typical data of this kind, taken for a variety of SCRs,
including standard SCRs, high speed SCRs, is con-
Q1 COL.
A
U2, P1
B
U4, P4
C
IGT
D
CONSTANT
CURRENT
GEN.
E
Q5 COL.
U2, P7
F
U5, P7
G
Q9 COL.
Q10−Q12
di/dt
CIRCUIT
IT
DUT
U6, P6
dv/dt
CIRCUIT
Q15
GATE
dv/dt
Q15
DRAIN
dv/dt
OUTPUT
H
I
J
K
L
0
200
400
600
800
t, TIME (μs)
Figure 5.6. tq Test Fixture System Waveforms
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I = 2 A/Div
0A
V = 10 V/Div
0V
tq = 63 μs
t = 50 μs/Div
t = 1 μs/Div
D1 = MR856, FAST RECOVERY RECTIFIER
I = 2 A/Div
0A
V = 10 V/Div
0V
tq = 59 μs
t = 1 μs/Div
t = 50 μs/Div
D1 = 1N5402, STANDARD RECOVERY RECTIFIER
Figure 5.7. The Effects of Blocking Diode D1 on tq of a 2N6508 SCR
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Table 5.1. Parameters Affecting tq
Device
2N6508
25 A
600 V
2N6399
12 A
A
B
C
D
E
F
G
H
I
RGK = 1 k
dv/dt = 15 V/μs
ITM = 25 A
IRM = 14 A
di/dt = − 100 A/μs
ITM duration = 275 μs
IGT = 30 mA
RGK = 100
dv/dt = 2.4 V/μs
ITM = 1 A
IRM = 1.8 A
di/dt = 32 A/μs
RGK = 100
dv/dt = 2.4 V/μs
ITM = 2 A
IRM = 50 mA
di/dt = 0.5 μs
RGK = 100
dv/dt = 2.4 V/μs
IRM = 50 mA
di/dt = 0.45 A/μs
RGK = 100
dv/dt = 2.4 V/μs
RGK = dv/dt = 2.4 V/μs
RGK = 100
dv/dt = 2.4 V/μs
ITM = 37 A
RGK = 100
IGT = 90 mA
typ tq = 68 μs
typ tq = 42 μs
typ tq = 45 μs
typ tq = 49 μs
typ tq = 60 μs
typ tq = 64 μs
typ tq = 64 μs
typ tq = 65 μs
typ tq = 68 μs
RGK = 1 k
dv/dt = 90 V/μs
ITM = 12 A
IRM = 11 A
di/dt = − 100 A/μs
ITM duration = 275 μs
IGT = 30 mA
RGK = 100
dv/dt = 2.5 V/μs
ITM = 1 A
IRM = 50 mA
di/dt = − 0.5 A/μs
RGK = 100
dv/dt = 2.5 V/μs
ITM = 1 A
IRM = 2.7 A
di/dt = 56 A/μs
RGK = 100
dv/dt = 2.5 V/μs
IRM = 50 mA
di/dt = 32 A/μs
RGK = 100
dv/dt = 2.5 V/μs
ITM = 18 A
IRM = 50 mA
di/dt = 0.3 A/μs
RGK = dv/dt = 2.5 V/μs
IRM = 50 mA
di/dt = 0.35 A/μs
RGK = 100
IGT = 90 mA
typ tq = 48 μs
typ tq = 30 μs
typ tq = 31 μs
typ tq = 32 μs
typ tq = 33 μs
typ tq = 35.5 μs
typ tq = 45 μs
typ tq = 48 μs
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Table 5.1. Continued
Device
C106B
4A
2N6240
4A
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MCR100−6
0.8 A
2N5064
0.8 A
2N5061
0.8 A
A
B
C
E
F
G
H
I
ITM = 6 A
IRM = 0.1 A
di/dt = −1 A/ms
VDX = 50 V
dv/dt = 1.4 V/ms
ITM = 2 A
IRM = 0.2 A
di/dt = −1.4 A/ms
−V2 = 35 V
IRM = 0.2 A
di/dt = −1.4 A/ms
IRM = 0.15 A
−V2 = 4 V
di/dt = −1.4 A/ms
dv/dt = 1.4 V/ms
IRM = 0.15 A
di/dt = 1.4 A/ms
IGT = 90 mA
dv/dt = 1.4 V/ms
IRM = 2 A
di/dt = −1.4 A/ms
typ tq = 26 ms
typ tq = 26 ms
typ tq = 26 ms
typ tq = 27 ms
typ tq = 27 ms
typ tq = 27 ms
typ tq = 27 ms
RGK = 100
dv/dt = 1.3 V/ms
ITM = 1 A
IRM = 50 mA
di/dt = −0.5 A/ms
IGT = 90 mA
VDX = 150 V
RGK = 100
dv/dt = 1.75 V/ms
ITM = 1 A
IRM = 50 mA
di/dt = −0.5 A/ms
IGT = 90 mA
RGK = 100
dv/dt = 1.75 V/ms
IRM = 50 mA
di/dt = −0.5 A/ms
IGT = 90 mA
dv/dt = 1.75 V/ms
RGK = 100
ITM = 6 A
IRM = 50 mA
di/dt = −0.5 A/ms
IGT = 90 mA
RGK = 100
IRM = 50 mA
di/dt = −0.5 A/ms
IGT = 90 mA
RGK = 100
IGT = 900 mA
RGK = dv/dt = 1.75 V/ms
ITM = 1 A
IRM = 50 mA
di/dt = −0.5 A/ms
IGT = 90 mA
IGT = 90 mA
typ tq = 44.8 ms
typ tq = 26 ms
typ tq = 26.2 ms
typ tq = 27.7 ms
typ tq = 28.6 ms
typ tq = 30 ms
typ tq = 32.7 ms
typ tq = 37.2 ms
typ tq = 41.4 ms
RGK = 1 k
dv/dt = 160 V/ms
ITM = 0.8 A
IRM = 0.8 A
di/dt = 12 A/ms
VDX = 50 V
ITM duration = 275 ms
dv/dt = 30 V/ms
ITM = 0.25 A
IRM = 40 mA
di/dt = −0.6 A/ms
dv/dt = 30 V/ms
Ir = 40 mA
di/dt = −0.8 A/ms
−V2 = 9 V
IRM = 20 mA
di/dt = −0.4 A/ms
−V2 = 1 V
Ir = 40 mA
di/dt = −0.8 A/ms
dv/dt = 30 V/ms
ITM = 1.12 A
IRM = 40 mA
di/dt = −0.8 A/ms
dv/dt = 30 V/ms
ITM = 1.12 A
IRM = 40 mA
di/dt = −0.8 A/ms
VDX = 100 V
typ tq = 14.4 ms
typ tq = 12.7 ms
typ tq = 13.5 ms
typ tq = 13.7 ms
typ tq = 13.9 ms
typ tq = 14.4 ms
typ tq = 14.4 ms
RGK = 1 k
dv/dt = 30 V/ms
ITM = 0.8 A
IRM = 0.8 A
di/dt = 12 A/ms
ITM duration = 275 ms
VDX = 50 V
dv/dt = 5 V/ms
ITM = 0.2 A
IRM = 50 mA
di/dt = −0.6 A/ms
dv/dt = 5 V/ms
IRM = 50 mA
di/dt = −0.8 A/ms
dv/dt = 5 V/ms
ITM = 1.12 A
IRM = 50 mA
di/dt = −0.8 A/ms
IRM = 40 mA
−V2 = 9 V
di/dt = −0.45 A/ms
IRM = 40 mA
−V2 = 1 V
di/dt = −0.8 A/ms
VDX = 100 V
dv/dt = 5 V/ms
ITM = 1.12 A
IRM = 50 mA
di/dt = −0.8 A
typ tq = 28.9 ms
typ tq = 27/ms
typ tq = 30/ms
typ tq = 31 ms
typ tq = 31.2 ms
typ tq = 31.4 ms
typ tq = 31.7 ms
dv/dt = 10 V/ms
ITM = 0.8 A
IRM = 0.8 A
di/dt = 18 A/ms
ITM duration = 275 ms
RGK = 1 k
VDX = 30 V
dv/dt = 3.5 V/ms
ITM = 0.25 A
IRM = 40 mA
di/dt = −0.7 A/ms
dv/dt = −3.5 V/ms
IRM = 40 mA
di/dt = −0.8 A/ms
dv/dt = 3.5 V/ms
ITM = 1.12 A
IRM = 40 mA
di/dt = −0.8 A/ms
VDX = 60 V
dv/dt = 3.58/ms
ITM = 1.12 A
IRM = 40 mA
di/dt = −0.7 A/ms
−V2 = 4 V
IRM = 20 mA
di/dt = −0.2 A/ms
−V2 = 1 V
IRM = 40 mA
di/dt = −0.8 A/ms
typ tq = 31.7 ms
typ tq = 19.1 ms
typ tq = 19/ms
typ tq = 19.8 ms
typ tq = 30 ms
typ tq = 30.2 ms
IGT = 1 mA
RGK = 1 k
dv/dt = 5 V/ms
ITM = 4A
IRM = 4A
di/dt = 50 A/ms
ITM duration = 275 ms
VDX = 50 V
ITM = 2 A
IRM = 2.5 A
di/dt = −30 A/ms
VDX = 50 V
ITM = 6 A
IRM = −1 A/ms
di/dt = −1 A/ms
VDX = 150 V
typ tq = 28 ms
typ tq = 25 ms
RGK = 1 k
dv/dt = 40 V/ms
ITM = 4 A
IRM = 4 A
di/dt = 50 A/ms
ITM duration = 275 ms
IGT = 1 mA
VDX = 50 V
D
typ tq = 20.2 ms
Table 5.2 is a condensed summary of Table 5.1 and
shows what happens to the tq of the different devices when
a parameter is varied in one direction or the other.
Parameter Changed
IGT Increase
Device
2N6508
2N6399
2N6240
C106F
Columns
AI
AG
AI
HI
1st
(μs)
68
48
44.8
27
2nd
(μs)
68
48
41.4
27
Decrease RGK
1 k to 100 ohms
2N6508
2N6399
2N6240
AH
AG
GI
68
48
41.4
65
45
32.7
Increase RGK
1 k to 2N6508
2N6399
2N6240
EF
DF
CH
60
32
26.2
64
35.5
37.2
VDX
C106F
2N6240
MCR100−6
2N5064
2N5061
DC
BC
FG
DG
DE
26
26.2
14.4
31
20.2
26
26
14.4
31.7
19.8
Decrease dv/dt Rate
2N6508
C106F
2N6240
EH
HJ
DF
65
29
30
60
27
27.7
EG
DE
EH
DC
DE
CE
CF
CD
BE
60
32
26
26.2
27.7
26.2
13.5
30.7
19.1
64
33
27
27.7
28.6
28.6
14.4
31
20.7
THE EFFECT OF CHANGING PARAMETERS
ON tq
From Tables 5.1 and 5.2, it is clear that some
parameters affect tq more than others. The following
discussion describes the effect on tq of the various
parameters.
FORWARD CURRENT MAGNITUDE (ITM)
Of the parameters that were investigated, forward−current magnitude and the di/dt rate have the strongest effect
on tq. Varying the ITM magnitude over a realistic range of
ITM conditions can change the measured tq by about 30%.
The change in tq is attributed to varying current densities
(stored charge) present in the SCR’s junctions as the ITM
magnitude is changed. Thus, if a large SCR must have a
short tq when a low ITM is present, a large gate trigger
pulse (IGT magnitude) would be advantageous. This turns
on a large portion of the SCR to minimize the high current
densities that exists if only a small portion of the SCR
were turned on (by a weak gate pulse) and the low ITM did
not fully extend the turned on region.
In general, the SCR will exhibit longer tq times with
increasing ITM. Increasing temperature also increases the
tq time.
Increase ITM
2N6508
2N6399
C106F
2N6240
MCR100−6
2N5064
2N5061
Table 5.2. The Effects of Changing Parameters on tq
di/dt RATE
Varying the turn−off rate of change of anode current
di/dt does have some effect on the tq of SCRs. Although
the increase in tq versus increasing di/dt was nominal for
the SCRs illustrated, the percentage change for the fast
SCRs was fairly high (about 30−40%).
By using different series inductors and changing the
negative anode turn−off voltage, it is possible to keep the
di/dt rate constant while changing IRM. It was found that
IRM has little or no effect on tq when it is the only variable
changed (see Table 5.1 C106F, Columns F and G, for
example).
REVERSE CURRENT MAGNITUDE (IRM)
The reverse current is actually due to the stored
charge clearing out of the SCR’s junctions when a
negative voltage is applied to the SCR anode. IRM is
very closely related to the di/dt rate; an increasing di/dt
rate causing an increase of IRM and a decreasing di/dt
rate causing a lower IRM.
REVERSE ANODE VOLTAGE (VRM)
Reverse anode voltage has a strong effect on the IRM
magnitude and the di/dt rate, but when VRM alone is
varied, with IRM and di/dt held constant, little or no
change in tq time was noticed. VRM must always be within
the reverse voltage of the device.
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Gate Bias
Conditions
+ V1
RI
dv/dt (v/μs)
− V2 = −10 V, IF = 3 A
50 V
1 k/50
2.5/50
0V
−5V
tq1
tq2
Diode
DI
dv/dt
(V/μs)
2N6508
40 μs
30 μs
Slow
MR502
2.5
Slow diode faster than fast diode, (lower tq)
2N6240
16 μs
9 μs
Slow
2.5
Slow diode faster. 2.5 V/μs faster than 50 V/μs
2N6399
30 μs
25 μs
Slow
2.5
Tested slow diode only
C106F
13 μs
8 μs
Slow
2.5
Tested slow diode only
Device
Remarks
Table 5.3 The Effects of Gate Bias on tq
25
tq , TURN-OFF TIME μ
( s)
20
MAGNITUDE LIMIT OF REAPPLIED dv/dt (VDX)
di/dt
STANDARD SCR
C106
dv/dt
RGK
TA
C106F
15
:
:
:
:
Changing the magnitude limit of the reapplied dv/dt
voltage has little or no effect on a given SCR’s tq time
when the maximum applied voltage is well below the
voltage breakdown of the SCR. The tq times will lengthen
if the SCR is being used near its voltage breakdown, since
the leakage present near breakdown is higher than at
lower voltage levels. The leakage will lengthen the time it
takes for the charge to be swept out of the SCR’s center
junction, thus lengthening the time it takes for this
junction to return to the blocking state.
5 A/μs
45 V/μs
100 Ω
25°C
10
5
0
1
2
5
10
20
50
GATE CATHODE RESISTANCE (RGK)
ITM, ANODE CURRENT (AMPS)
In general, the lower the RGK is, the shorter the tq time
will be for a given SCR. This is because low RGK aids in
the removal of stored charge in the SCR’s junctions. An
approximate 15% change in the tq time is seen by
changing RGK from 100 ohms to 1000 ohms for the DUTs.
Figure 5.8. Standard SCR Turn−Off Time tq as a
Function of Anode Current ITM
GATE DRIVE MAGNITUDE (IGT)
Changing the gate drive magnitude has little effect on a
SCR’s tq time unless it is grossly overdriven or underdriven. When it is overdriven, there is an unnecessary large
amount of charge in SCR’s junction. When underdriven, it
is possible that only a small portion of the chip at the gate
region turns on. If the anode current is not large enough to
spread the small turned on region, there is a high current
and charge density in this region that consequently
lengthens the tq time.
REAPPLIED dv/dt RATE
Varying the reapplied dv/dt rate across the range of
dv/dt’s commonly encountered can vary the tq of a given
SCR by more than 10%. The effect of the dv/dt rate on tq
is due to the Anode−Gate capacitance. The dv/dt applied
at the SCR anode injects current into the gate through this
capacitance (iGT = C dv/dt). As the dv/dt rate increased,
the gate current also increases and can trigger the SCR on.
To complicate matters, this injected current also adds to
the current due to leakage or stored charge left in the
junctions just after turn−off.
The stored charge remaining in the center junction is
the main reason for long tq times and, for the most part,
the charge is removed by the recombination process. If the
reapplied dv/dt rate is high, more charge is injected into
this junction and prevents it from returning to the
blocking state, as soon as if it were a slow dv/dt rate. The
higher the dv/dt rate, the longer the tq times will be.
FORWARD CURRENT DURATION
Forward current duration had no measurable effect on tq
time when varied from 100 μs to 300 μs, which were the
limits of the ON Semiconductor tq Tester. Longer ITM
durations heat up the SCR which causes temperature
effects; very short ITM durations affect the tq time due to
the lack of time for the charges in the SCR’s junctions to
reach equilibrium, but these effects were not seen in the
range tested.
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REVERSE GATE BIAS VOLTAGE
shorted transistor would cause the output voltage to
rise. Nor does it take into account overvoltage due to
transients on the output bus or accidental power supply
hookup. For these types of operations, the crowbar SCR
should be considered.
As in transistor operation, reverse biasing the gate of
the SCR decreases the turn−off time, due to the rapid
“sweeping out” of the stored charge. The reduction in tq
for standard SCRs is quite pronounced, approaching
perhaps 50% in some cases; for fast SCRs, only nominal
improvement might result. Table 5.3 shows this effect on
six SCRs where the gate bias was set for 0 V and − 5 V,
respectively (the 1 k gate resistor of the DUT was either
grounded or returned to − 5 V). Due to the internal,
monolithic resistor of most SCRs, the actual reverse bias
voltage between the gate−cathode is less than the reverse
bias supply.
HOW MUCH OVERVOLTAGE CAN THE
LOAD TAKE?
Crowbar protection is most often needed when ICs are
used, particularly those requiring a critical supply voltage
such as TTL or expensive LSI memories and MPUs.
If the load is 5 V TTL, the maximum specified
continuous voltage is 7 V. (CMOS, with its wide power
supply range of 3 to 18 V, is quite immune to most
overvoltage conditions.) But, can the TTL sustain 8 V or
10 V or 15 V and, if so, for how long and for how many
power cycles? Safe Operating Area (SOA) of the TTL
must be known. Unfortunately, this information is not
readily available and has to be generated.
CHARACTERIZING SCRs FOR CROWBAR
APPLICATIONS
The use of a crowbar to protect sensitive loads from
power supply overvoltage is quite common and, at the
first glance, the design of these crowbars seems like a
straightforward, relatively simple task. The crowbar SCR
is selected so as to handle the overvoltage condition and a
fuse is chosen at 125 to 250% of the supply’s rated
full−load line current. However, upon further investigation, other questions and problems are encountered.
How much overvoltage and for how long (energy) can
the load take this overvoltage? Will the crowbar respond
too slowly and thus not protect the load or too fast
resulting in false, nuisance triggering? How much energy
can the crowbar thyristor (SCR) take and will it survive
until the fuse opens or the circuit breaker opens? How fast
will the fuse open, and at what energy level? Can the fuse
adequately differentiate between normal current levels —
including surge currents — and crowbar short circuit
conditions?
It is the attempt of this section to answer these questions
— to characterize the load, crowbar, and fuse and thus to
match their characteristics to each other.
The type of regulator of most concern is the low
voltage, series pass regulator where the filter capacitors to
be crowbarred, due to 60 Hz operation, are relatively large
and the charge and energy stored correspondingly large.
On the other hand, switching regulators operating at about
20 kHz require smaller capacitors and thus have lower
crowbar constraints.
These regulators are quite often line−operated using a
high voltage, two−transistor inverter, half bridge or full
bridge, driving an output step−down transformer. If a
transistor were to fail, the regulator−transformed power
would be less and the output voltage would drop, not rise,
as is the case for the linear series regulator with a shorted
pass transistor. Thus, the need for overvoltage protection
of these types of switching regulators is minimized.
This premise, however, does not consider the case of
the lower power series switching regulator where a
20
V , SUPPLY VOLTAGE (VOLTS)
CC
TJ ≈ 85°C, DUTY CYCLE = 10%
VCC
18
5V
16
PULSE WIDTH
14
12
10
1
5
10
30 50
100
300 500
PULSE WIDTH (ms)
Figure 5.9. Pulsed Supply Voltage versus Pulse Width
Using the test circuit illustrated in Appendix III, a
quasi−SOA curve for a typical TTL gate was generated
(Figure 5.9). Knowing the overvoltage−time limit, the
crowbar and fuse energy ratings can be determined.
The two possible configurations are illustrated in
Figure 5.10, the first case shows the crowbar SCR across
the input of the regulator and the second, across the
output. For both configurations, the overvoltage comparator senses the load voltage at the remote load terminals,
particularly when the IR drop of the supply leads can be
appreciable. As long as the output voltage is less than that
of the comparator reference, the crowbar SCR will be in
an off state and draw no supply current. When an
over−voltage condition occurs, the comparator will produce a gate trigger to the SCR, firing it, and thus clamping
the regulator input, as in the first case — to the SCRs
on−state drop of about 1 to 1.5 V, thereby protecting the
load.
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(a). SCR Across Input of Regulator
D1
F
SERIES
REGULATOR
Vin
OVERVOLTAGE
SENSE
vO
Co
Cin
(b). SCR Across Output of Regulator
Vin
*
REGULATOR
OVERVOLTAGE
SENSE
vO
*NEEDED IF SUPPLY NOT CURRENT LIMITED
Figure 5.10. Typical Crowbar Configurations
Fuse selection is much easier as a fault will now give a
greater percentage increase in dc load current than when
measuring transformer primary or secondary rms current.
The disadvantage, however, of placing the fuse in the dc
load is that there is no protection for the input rectifier,
capacitor, and transformer, if one of these components
were to fail (short). Secondly, the one fuse must protect
not only the load and regulator, but also have adequate
clearing time to protect the SCR, a situation which is not
always readily accomplished. The input circuitry can be
protected with the addition of a primary fuse or a circuit
breaker.
Placing the crowbar across the input filter capacitors,
although effectively clamping the output, has several
disadvantages.
1. There is a stress placed on the input rectifiers during
the crowbarring short circuit time before the line fuse
opens, particularly under repeated operation.
2. Under low line conditions, the minimum short circuit
current can be of the same magnitude as the maximum
primary line current at high line, high load, making the
proper fuse selection a difficult choice.
3. The capacitive energy to be crowbarred (input and
output capacitor through rectifier D1) can be high.
When the SCR crowbar and the fuse are placed in the dc
load circuit, the above problems are minimized. If
crowbarring occurs due to an external transient on the line
and the regulator’s current limiting is working properly,
the SCR only has to crowbar the generally smaller output
filter capacitor and sustain the limited regulator current.
If the series pass devices were to fail (short), even with
current limiting or foldback disabled, the crowbarred
energy would generally be less than of the previous case.
This is due to the higher impedance of the shorted
regulator (due to emitter sharing and current sensing
resistors) relative to that of rectifier D1.
HOW MUCH ENERGY HAS TO BE
CROWBARRED?
This is dictated by the power supply filter capacitors,
which are a function of output current. A survey of several
linear power supply manufacturers showed the output
filter capacitor size to be from about 100 to 400
microfarads per ampere with about 200 μF/A being
typical. A 30 A regulator might therefore have a 6000 μF
output filter capacitor.
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Additionally, the usually much larger input filter
capacitor will have to be dumped if the regulator were to
short, although that energy to be dissipated will be
dependent on the total resistance in the circuit between
that capacitor and the SCR crowbar.
The charge to be crowbarred would be
If the peak current and/or duration of the surge is large,
destruction of the device due to excessive dissipation can
occur. Obviously, the ipk can be reduced by inserting
additional impedance in the crowbar path, at an increase
in dump time. However, this time, which is a measure of
how long the overvoltage is present, should be within the
SOA of the load.
The energy stored in the capacitor being a constant for a
particular voltage would suggest that the I2t integral for
any limiting resistance is also a constant. In reality, this is
not the case as the thermal response of the device must be
taken into consideration. It has been shown that the
dissipation capability of a device varies as to the t for the
first tens of milliseconds of the thermal response and, in
effect, the measure of a device’s energy capability would
Q CV I T,
the energy,
E 1
2 CV2
and the peak surge current
ipk VC
RT
When the SCR crowbars the capacitor, the current
waveform will be similar to that of Figure 5.11, with the
peak surge current, ipk, being a function of the total
impedance in the circuit (Figure 5.12) and will thus be
limited by the Equivalent Series Resistance (ESR) and
inductance (ESL) of the capacitor plus the dynamic
impedance of the SCR, any external current limiting
resistance, (and inductance) of the interconnecting wires
and circuit board conductors.
The ESR of computer grade capacitors, depending on
the capacitor size and working voltage, might vary from
10 to 1000 milliohms (mΩ). Those used in this study were
in the 25 to 50 mΩ range.
The dynamic impedance of the SCR (the slope of the
on−state voltage, on−state current curve), at high currents,
might be in the 10 to 20 mΩ range. As an example, from
the on−state characteristics of the MCR70, 35 A rms SCR,
the dynamic impedance is
rd DV F
DIF
be closer to i2 t. This effect is subsequently illustrated in
the empirically derived ipk versus time derating curves
being a non−linear function. However, for comparison
with fuses, which are rated in I2t, the linear time base, “t,”
will be used.
The di/dt of the current surge pulse is also a critical
parameter and should not exceed the device’s ratings
(typically about 200 A/μs for 50 A or less SCRs). The
magnitude of di/dt that the SCR can sustain is controlled
by the device construction and, to some extent, the gate
drive conditions. When the SCR gate region is driven on,
conduction across the junction starts in a small region and
progressively propagates across the total junction. Anode
current will initially be concentrated in this small
conducting area, causing high current densities which can
degrade and ultimately destroy the device. To minimize
this di/dt effect, the gate should be turned on hard and fast
such that the area turned on is initially maximized. This
can be accomplished with a gate current pulse approaching five times the maximum specified continuous gate
current, Igt, and with a fast rise time (< 1 μs). The gate
current pulse width should be greater than the propagation
time; a figure of 10 μs minimum should satisfy most
SCRs with average current ratings under 50 A or so.
The wiring inductance alone is generally large enough
to limit the di/dt. Since most SCRs are good for over
100 A/μs, this effect is not too large a problem. However,
if the di/dt is found excessive, it can be reduced by placing
an inductance in the loop; but, again, this increases the
circuit’s response time to an overvoltage and the trade−off
should be considered.
(4.5 3.4)V
1.1 V 11 mΩ.
(300 200)A
100 A
The interconnecting wire might offer an additional
5 mΩ (#20 solid copper wire 20 mΩ/ft) so that the total
circuit resistance, without additional current limiting,
might be in the 40 to 70 mΩ range. The circuit inductance
was considered low enough to ignore so far as ipk is
concerned for this exercise, being in hundreds of nanohenry range (ESL 3 nH, L wire 500 nH/ft).
However, di/dt will be affected by the inductance.
HOW MUCH ENERGY CAN THE CROWBAR SCR
SUSTAIN?
There are several factors which contribute to possible
SCR failures or degradation — the peak surge current,
di/dt, and a measure of the device’s energy capability, I2t.
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I
ipk
0
t = 0.5 ms/Div
50%
di/dt
10%
5τ
2.3 τ
tW
t
10%
tW
0
t = 10 μs/Div
I = 200 A/Div
MCR69
C = 22,000 μF
CROWBAR CURRENT TERMS
RS = 0
VC = 30 V
IGT = 200 mA
Figure 5.11. Typical SCR Crowbar Waveform
RW
LW
ESR
RS
ESL
LS
Since many SCR applications are for 60 Hz line
operation, the specified peak non−repetitive surge current
ITSM and circuit fusing I2t are based on 1/2 cycle (8.3 ms)
conditions. For some SCRs, a derating curve based on up
to 60 or 100 cycles of operation is also published. This
rating, however, does not relate to crowbar applications.
To fully evaluate a crowbar system, the SCR must be
characterized with the capacitor dump exponential surge
current pulse.
A simple test circuit for deriving this pulse is shown in
Figure 5.13, whereby a capacitor is charged through a
limiting resistor to the supply voltage, V, and then the
charge is dumped by the SCR device under test (DUT).
The SCR gate pulse can be varied in magnitude, pulse
width, and rise time to produce the various IGT conditions.
An estimate of the crowbar energy capability of the DUT
is determined by first dumping the capacitor charged to
low voltage and then progressively increasing the voltage
until the DUT fails. This is repeated for several devices to
establish an average and minimum value of the failure
points cluster.
RW, LW: INTERCONNECTING WIRE IMPEDANCE
RS, LS: CURRENT LIMITING IMPEDANCE
Figure 5.12. Circuit Elements Affecting SCR
Surge Current
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100
DUT
22,000 μF
V
50
H.P. 214A
PULSE
GENERATOR
EXTERNAL
TRIGGER
Figure 5.13
This procedure was used to test several different SCRs
of which the following Table 5.4 describes several of the
pertinent energy specifications and also the measured
crowbar surge current at the point of device failure.
This one−shot destruct test was run with a gate current
of five IGT(MAX) and a 22,000 μF capacitor whose ESR
produced the exponentially decaying current pulse about
1.5 ms wide at its 10% point. Based on an appropriate
derating, ten devices of each line where then successfully
tested under the following conditions.
Device
VC
ipk
t
2N6397
12 V
250 A
1.5 ms
2N6507
30 V
800 A
1.5 ms
about 1 mA/μs). Due to its energy limitations, the MCR68
was tested with only 10 V across the larger capacitors.
The slow ramp, IGT, was used to simulate overvoltage
sense applications where the gate trigger rise time can be
slow such as with a coupling zener diode.
No difference in SCR current characteristics were noted
with the different gate current drive conditions; the peak
currents were a function of capacitor voltage and circuit
impedance, the fall times related to RTC, and the rise
times, tr, and di/dt, were more circuit dependent (wiring
inductance) and less device dependent (SCR turn−on
time, ton). Since the wiring inductance limits, tr, the
effect of various IGTs was masked, resulting in virtually
identical waveforms.
The derated surge current, derived from a single (or low
number) pulse test, does not truly reflect what a power
supply crowbar SCR might have to see over the life of the
supply. Life testing over many cycles have to be
performed; thus, the circuit described in Appendix IV was
developed. This life test fixture can simultaneously test
ten SCRs under various crowbar energy and gate drive
conditions.
To determine the effect of gate drive on the SCRs, three
devices from each line were characterized at non−destruct
levels using three different capacitors (200, 6,000, and
22,000 μF), three different capacitor voltages (10, 20, and
30 V), and three different gate drives (IGT(MAX),
5 IGT(MAX), and a ramp IGT(MAX) with a di/dt of
Table 5.4. Specified and Measured Current Characteristics of Three SCRs
Measured Crowbar
Surge Current Ipk
Maximum Specified Values
Device
Case
IT(rms)
(A)
IT(AV)
(A)
ITSM*
(A)
I2t
(A2s)
IGT(Max)
(mA)
Min
(A)
Max
(A)
Ave
(A)
2N6397
TO−220
12
8
100
40
30
380
750
480
2N6507
TO−220
25
16
300
375
40
1050
1250
1100
* ITSM = Peak Non−Repetitive Surge Current, 1/2 cycle sine wave, 8.3 ms.
Each of the illustrated SCRs of Figure 5.14(a) were tested
with as many as four limiting resistors (0, 50, 100, and
240 mΩ) and run for 1000 cycles at a nominal energy level.
If no failures occurred, the peak current was progressively
increased until a failure(s) resulted. Then the current was
reduced by 10% and ten new devices were tested for 2000
cycles (about six hours at 350 cycles/hour). If this test
proved successful, the data was further derated by 20% and
plotted as shown on log−log paper with a slope of − 1/4. This
theoretical slope, due to the I2 t one−dimensional heat−flow
relationship (see Appendix VI), closely follows the empirical results. Of particular interest is that although the peak
current increases with decreasing time, as expected, the I2t
actually decreases.
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1
Ipk
TA = 25°C
N = 2000 PULSES
f = 3 PULSES/MIN.
3000
tW
NORMALIZED PEAK SURGE CURRENT
Ipk , PEAK CURRENT (AMPS)
C = 8400 μF
ESR ≈ 25 mΩ
VC 60 V
5 TC
1000
2N6507
300
2N6397
100
30
N = 2000 PULSES
0.8
0.6
0.4
0.2
0.1
0.5
1
5
10
tW, BASE PULSE WIDTH (ms)
50 100
0
25
50
75
100
125
TC, AMBIENT TEMPERATURE (°C)
Figure 5.14(a). Peak Surge Current versus Pulse Width
(b). Peak Surge Current versus Ambient Temperature
Once an overvoltage is detected and the crowbar is
enabled, in addition to sustaining the peak current, the
SCR must handle the regulator short−circuit current for
the time it takes to open the fuse.
Thus, all three elements are tied together — the load
can take just so much overvoltage (over−energy) and the
crowbar SCR must repeatedly sustain for the life of the
equipment an rms equivalent current pulse that lasts for
the fuse response time.
It would seem that the matching of the fuse to the SCR
would be straightforward — simply ensure that the fuse
rms current rating never exceed the SCR rms current
rating (Figure 5.15), but still be sufficient to handle
steady−state and normal overload currents. The more
exact relationship would involve the energy dissipated in
the system ∫ I2Rdt, which on a comparative basis, can be
reduced to I2t. Thus, the “let−through” I2t of the fuse
should not exceed I2t capability of the SCR under all
operating conditions. These conditions are many, consisting of “available fault current,” power factor of the load,
supply voltage, supply frequency, ambient temperature,
and various fuse factors affecting the I2t.
There has been much detailed information published on
fuse characteristics and, rather than repeat the text which
would take many pages, the reader is referred to those
sources. Instead, the fuse basics will be defined and an
example of matching the fuse to the SCR will be shown.
In addition to interrupting high current, the fuse should
limit the current, thermal energy, and overvoltage due to
the high current. Figure 5.16 illustrates the condition of
the fuse at the moment the over−current starts. The peak
let−through current can be assumed triangular in shape for
a first−order approximation, lasting for the clearing time
of the fuse. This time consists of the melting or pre−arcing
time and the arcing time. The melting time is an inverse
function of over−current and, at the time that the fuse
element is opened, an arc will be formed causing the peak
arc voltage. This arc voltage is both fuse and circuit
dependent and under certain conditions can exceed the
Figure 5.14(b) shows the effect of elevated ambient
temperature on the peak current capability of the
illustrated SCRs.
FUSE CHARACTERISTICS
SCRs, like rectifiers, are generally rated in terms of
average forward current, IT(AV), due to their half−wave
operation. Additionally, an rms forward current, IT(rms), a
peak forward surge current, ITSM, and a circuit−fusing
energy limit, I2t, may be shown. However, these specifications, which are based one−half cycle 60 Hz operation,
are not related to the crowbar current pulse and some
means must be established to define their relationship.
Also, fuses which must ultimately match the SCR and the
load, are rated in rms currents.
The crowbar energy curves are based on an exponentially decaying surge current waveform. This can be
converted* to Irms by the equation.
Irms 0.316 i pk
which now allows relating the SCR to the fuse.
*See Appendix V
The logic load has its own overvoltage SOA as a
function of time (Figure 5.9). The crowbar SCR must
clamp the overvoltage within a specified time, and still be
within its own energy rating; thus, the series−limiting
resistance, RS, in the crowbar path must satisfy both the
load and SCR energy limitations. The overvoltage
response time is set by the total limitations. The
overvoltage response time is set by the total limiting
resistance and dumped capacitor(s) time constant. Since
the SOA of the TTL used in this exercise was derived by a
rectangular overvoltage pulse (in effect, over−energy), the
energy equivalent of the real−world exponentially falling
voltage waveform must be made. An approximation can
be made by using an equivalent rectangular pulse of 0.7
times the peak power and 0.7 times the base time.
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Two other useful curves, the total clearing I2t characteristic and the peak let−through current IPLT characteristic,
are illustrated in Figures 5.17 and 5.18 respectively. Some
vendors also show total clearing time curves (overlayed
on Figure 5.17 as dotted lines) which then allows direct
comparison with the SCR energy limits. When this
clearing time information is not shown, then the designer
should determine the IPLT and I2t from the respective
curves and then solve for the clearing time from the
approximate equation relating these two parameters.
Assuming a triangular waveform for IPLT, the total
clearing time, tc, would then approximately be
CURRENT I rms (LOG)
peak line voltage, a condition the user should ensure does
not overstress the electronics.
The available short−circuit current is the maximum
current the circuit is capable of delivering and is generally
limited by the input transformer copper loss and reactance
when the crowbar SCR is placed at the input to the
regulator or the regulator current limiting when placed at
the output. For a fuse to safely protect the circuit, it should
limit the peak let−through current and clear the fault in a
short time, usually less than 10 ms.
2
tc ≈ 3 I t
IPLT2
SCR CHARACTERISTICS
Once tc of the fuse is known, the comparison with the
SCR can readily be made. As long as the I2t of the fuse is
less than the I2t of the SCR, the SCR is protected. It
should be pointed out that these calculations are predicated on a known value of available fault current. By
inspection of Figure 5.18, it can be seen that IPLT can vary
greatly with available fault current, which could have a
marked effect on the degree of protection. Also, the
illustrated curves are for particular operating conditions;
the curves will vary somewhat with applied voltage and
frequency, initial loading, load power factor, and ambient
temperature. Therefore, the reader is referred to the
manufacturer ’s data sheet in those cases where extrapolation will be required for other operating conditions. The
final proof is obtained by testing the fuse in the actual
circuit under worst−case conditions.
FUSE
CHARACTERISTIC
Irms (max)
LIMITED BY FUSE
10 ms
4 HRS
TIME t (LOG)
Figure 5.15. Time−Current Characteristic Curves
of a Crowbar SCR and a Fuse
FUSE VOLTAGE
PEAK ARC VOLTAGE
SUPPLY
VOLTAGE
INSTANT OF SHORT
FUSE CURRENT
CROWBAR EXAMPLE
To illustrate the proper matching of the crowbar SCR to
the load and the fuse, consider the following example. A
50 A TTL load, powered by a 60 A current limited series
regulator, has to be protected from transients on the
supply bus by crowbarring the regulator output. The
output filter capacitor of 10,000 μF (200 μF/A) contributes most of the energy to be crowbarred (the input
capacitor is current limited by the regulator). The
transients can reach 18 V for periods 100 ms.
Referring to Figure 5.9, it is seen that this transient
exceeds the empirically derived SOA. To ensure safe
operation, the overvoltage transient must be crowbarred
within 5 ms. Since the TTL SOA is based on a rectangular
power pulse even though plotted in terms of voltage, the
equivalent crowbarred energy pulse should also be
derived. Thus, the exponentially decaying voltage waveform should be multiplied by the exponentially decaying
current to result in an energy waveform proportional to
e−2x. The rectangular equivalent will have to be determined and then compared with the TTL SOA. However,
for simplicity, by using the crowbarred exponential
waveform, a conservative rating will result.
MELTING TIME
ARCING TIME
CLEARING TIME
PEAK ASYMMETRICAL
FAULT CURRENT
PEAK FUSE CURRENT
IPLT
Figure 5.16. Typical Fuse Timing Waveforms During
Short Circuit
Fuse manufacturers publish several curves for characterizing their products. The current−time plot, which
describes current versus melting time (minimum time
being 10 ms), is used in general industrial applications,
but is not adequate for protecting semiconductors where
the clearing time must be in the subcycle range. Where
protection is required for normal multicycle overloads,
this curve is useful.
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4
SF 13X SERIES
130 Vrms, 60 Hz
TA = 25°C
POWER FACTOR 15%
LET-THROUGH I2 t (A2 S)
102
20 A
15 A
4
10 A
10
4
5 ms
1
10
2 ms 1.5 ms
TOTAL CLEARING TIME
102
4
103
4
104
AVAILABLE FAULT CURRENT (SYMMETRICAL rms AMPS)
4
105
4
Figure 5.17. Maximum Clearing I2t Characteristics for 10 to 20 A Fuses
If a crowbar discharge time of 3 ms were chosen, it
would not only be within the rectangular pulsed SOA, but
also be well within the derived equivalent rectangular
model of the exponential waveform. It would also require
about 1.3 time constants for the overvoltage to decay from
18 V to 5 V; thus, the RC time constant would be 3 ms/1.3
or 2.3 ms.
The limiting resistance, RS would simply be
INSTANTANEOUS PEAK LET-THROUGH CURRENT (AMPS
To protect the SCR, a fuse must be chosen that will
open before the SCR’s I2t is exceeded, the current being
the regulator limiting current which will also be the
available fault current to the fuse.
The fuse could be eliminated by using a 60 A SCR, but
the cost versus convenience trade−off of not replacing the
fuse is not warranted for this example. A second fuse or
circuit breaker will protect the rectifiers and regulator for
internal faults (shorts), but its selection, which is based on
the respective energy limits of those components, is not
part of this exercise.
RS 103
4
2.3 ms 0.23 W 0.2 W
10, 000 mF
20 A
MAX PEAK AVAILABLE CURRENT
(2.35 x SYMMETRICAL rms AMPERES)
15 A
10 A
102
4
SF 13X SERIES
130 Vrms, 60 Hz
POWER FACTOR 15%
10
10
4
102
4
103
4
104
AVAILABLE FAULT CURRENT (SYMMETRICAL rms AMPS)
4
105
Figure 5.18. Peak Let−Through Current versus Fault Current for 10 to 20 A Fuses
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I2t rating is not specified, but can be calculated from the
equation
Since the capacitor quickly charges up to the over−voltages
VCC1 of 18 V, the peak capacitor discharge current would be
Ipk V CC1
18 V 90 A
0.2 W
RS
I 2t Irms 0.316 I pk 0.316(90) 28.4 A rms
Now referring to the SCR peak current energy curves
(Figure 5.14), it is seen that the MCR68 can sustain 210 A
peak for a base time of 3 ms. This 12 A SCR must also
sustain the 60 A regulator limited current for the time
required to open the fuse. The MCR68 has a specified
peak forward surge current rating of 100 A (1/2 cycle, sine
wave, 60 Hz, non−repetitive) and a circuit fusing rating of
40 A2s.
The non−repetitive rating implies that the device can
sustain 100 occurrences of this 1/2 cycle surge over the
life of the device; the SCR crowbar surge current curves
were based on 2000 cycles.
For the 3 ms time frame, the I12t1 for the exponential
waveform is
2
3(10)
tc 3 I t 6.1 ms
I PLT2
(70)2
Assuming that the fuse will open within 6 ms, the
approximate energy that the SCR must sustain would be
60 A for an additional 3 ms. By superposition, this would
amount to
The fuse is now matched to the SCR which is matched to
the logic load. Other types of loads can be similarly
matched, if the load energy characteristics are known.
CHARACTERIZING SWITCHES AS LINE−TYPE
MODULATORS
2
I2 t2 (60 A) 2(6 ms) 21.6 A 2s
In the past, hydrogen thyratrons have been used
extensively as discharge switches for line type modulators. In general, such devices have been highly satisfactory from an electrical performance standpoint, but they
have some major drawbacks including relatively large
size and weight, low efficiency (due to filament power
requirements), and short life expectancy compared with
semiconductor devices, now can be eliminated through
the use of silicon controlled rectifiers.
A line type modulator is a modulator whose output−
pulse characteristics are determined by a lumped−
constant transmission line (pulse forming network) and by
the proper match of the line impedance (PFN) to the load
impedance.
A switch for this type modulator should only initiate
conduction and should have no effect on pulse characteristics. This is in contrast to a hard switch modulator where
output pulse characteristics are determined by the “hard”
relationship of grid (base) control of conduction through a
vacuum tube (transistor) switch.
Referring to the schematic (Figure 5.25), when the
power supply is first turned on, no charge exists in the
PFN, and energy is transferred from the power supply to
the PFN via the resonant circuit comprising the charging
choke and PFN capacitors. At the time that the voltage
which , when added to the exponential energy, would
result in 24 A2.
The MCR68 has a 40 A2 s rating based on a 1/2 cycle
of 8.3 ms. Due to the one−dimensional heat flow in the
device, the energy capability is not linearly related to
time, but varies as to the t. Therefore, with a 6 ms
1/2−cycle sine wave, the 40 A2 t rating would now
decrease to approximately (see Appendix VI for
derivation).
40 A 2s
1
2
6 ms 8.3
ms
(300 A) 2
(8.3 ms) 375 A2s
2
Figure 5.18 illustrates that for the same conditions,
instantaneous peak let−through current of about 70 A
would result. For fuse manufacturers that don’t show the
clearing time information, the approximate time can be
calculated from the triangular model, as follows
I1 t1 (28.4 A) 2(3 ms) 2.4 A 2s
t2
I2 t 2 I 1 t 1
t1
t
I2t fuse I 2t SCR
tc 6 ms
2
2
2
Extrapolating to 6 ms results in about 318 A2s, an I2t
rating much greater than the circuit 24 A2s value.
The circuit designer can then make the cost/performance trade−offs.
All of these ratings are predicated on the fuse operating
within 6 ms.
With an available fault current of 60 A, Figure 5.17
shows that a 10 A (SF13X series) fuse will have a
let−through I2t of about 10 A2s and a total clearing time of
about 6 ms, satisfying the SCR requirements, that is,
The rms current equivalent for this exponentially decaying pulse would be
2
(I TSM)2
1
2
34 A 2s
Although the 1/2 cycle extrapolated rating is greater than
the actual crowbar energy, it is only characterized for 100
cycles of operation.
To ensure 2000 cycles of operation, at a somewhat
higher cost, the 25 A MCR69 could be chosen. Its
exponential peak current capability, at 3 ms, is about
560 A and has a specified ITSM of 300 A for 8.3 ms. The
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across the PFN capacitors reaches twice the power supply
voltage, current through the charging choke tries to
reverse and the power supply is disconnected due to the
back biased impedance of the hold−off diode. If we
assume this diode to be perfect, the energy remains stored
in the PFN until the discharge switch is triggered to its on
state. When this occurs, assuming that the pulse transformer has been designed to match the load impedance to
the PFN impedance, all energy stored in the PFN
reactance will be transferred to the load if we neglect
switch losses. Upon completion of the transfer of energy
the switch must return to its off condition before allowing
transfer of energy once again from the power supply to the
PFN storage element.
of 5 to 10 ohms or less. Operating the SCR at higher
current to switch the same equivalent pulse power as a
thyratron requires the SCR on impedance to be much
lower so that the I2R loss is a reasonable value, in order to
maintain circuit efficiency. Low switch loss, moreover, is
mandatory because internal power dissipation can be
directly translated into junction−temperature−rise and
associated leakage current increase which, if excessive,
could result in thermal runaway.
TURN−ON TIME
In radar circuits the pulse−power handling capability of
an SCR, rather than the normally specified average−
power capability, is of primary importance.
For short pulses at high PRFs the major portion of
semiconductor dissipation occurs during the initial
turn−on during the time that the anode rises from its
forward leakage value to its maximum value. It is
necessary, therefore, that turn−on time be as short as
possible to prevent excessive power dissipation.
The function of radar is to provide distance information
measured as a function of time. It is important, therefore,
that any delay introduced by a component be fixed in
relation to some variable parameter such as signal
strength or temperature. For radar pulse modulator
applications, a minimal delay variation versus temperature is required and any such variation must be repetitive
from SCR to SCR, in production lots, so that adequate
circuit compensation may be provided.
OPTIMUM SWITCH CHARACTERISTICS
FORWARD BREAKOVER VOLTAGE
Device manufacturers normally apply the variable−
amplitude output of a half−wave rectifier across the SCR.
Thus, forward voltage is applied to the device for only a
half cycle and the rated voltage is applied only as an ac
peak. While this produces a satisfactory rating for ac
applications, it does not hold for dc.
An estimated 90% of devices tested for minimum
breakover voltage (VBO) in a dc circuit will not meet the
data sheet performance specifications. A switch designed
for the pulse modulator application should therefore
specify a minimum continuous forward breakover voltage
at rated maximum leakage current for maximum device
temperatures.
PULSE GATE CURRENT TO FIRE
The time of delay, the time of rise, and the delay
variation versus temperature associated with SCR turn−on
are functions of the gate triggering current available and
the trigger pulse duration. In order to predict pulse circuit
operation of the SCR, the pulse gate current required to
turn the device on when switching the low−impedance
modulator should be specified and the limits of turn−on−
time variation for the specified pulse trigger current and
collector load should be given at the high and low
operating temperature extremes.
THE OFF SWITCH
The maximum forward leakage current of the SCR
must be limited to a low value at maximum device
temperature. During the period of device nonconduction it
is desired that the switch offer an off impedance in the
range of megohms to hundreds of megohms. This is
required for two reasons: (1) to prevent diminishing the
efficiency of recharge by an effective shunt path across
the PFN, and (2) to prevent the bleeding off of PFN charge
during the interpulse period. This second factor is
especially important in the design of radar tansponders
wherein the period between interrogations is variable.
Change of the PFN voltage during the interpulse period
could result in frequency shift, pulse instabilities, and loss
of power from the transmitter being modulated.
RECOVERY TIME
After the cessation of forward conducting current in the
on device, a time of SCR circuit isolation must be
provided to allow the semiconductor to return to its off
state. Recovery time cannot be given as an independent
parameter of device operation, but must include factors as
determined by the external circuit, such as: (1) pulse
current and rate of decay; (2) availability of an inverse
voltage immediately following pulse−current conduction;
(3) level of base bias following pulse current conduction;
(4) rate of rise of reapplied positive voltage and its
amplitude in relation to SCR breakover voltage; and
(5) maximum circuit ambient temperature.
THE ON SWITCH
At present, SCR design is more limited in the
achievable maximum forward sustaining voltage than in
the current that the device will conduct. For this reason
modulators utilizing SCRs can be operated at lower
impedance levels than comparable thyratron circuits of
yesterday. It is not uncommon for the characteristic
impedance of the pulse forming network to be in the order
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In the reverse direction the controlled rectifier behaves
like a conventional silicon diode. Under worst circuit
conditions, if an inverse voltage is generated through the
existence of a load short circuit, the current available will
be limited only by the impedance of the pulse forming
network and SCR inverse characteristics. The reverse
current is able to sweep out some of the carriers from the
SCR junctions. Intentional design of the load impedance
to something less than the network impedance allows
development of an inverse voltage across the SCR
immediately after pulse conduction, enhancing switch
turn−off time. Careful use of a fast clamp diode in series
with a fast zener diode, the two in shunt across the SCR,
allows application of a safe value of circuit−inverse−voltage without preventing the initial useful reverse current.
Availability of a negative base−bias following pulse
current conduction provides a similar enhancement of
switch turn−off time.
If removal of carriers from the SCR junction enables a
faster switch recovery time, then, conversely, operation of
the SCR at high temperatures with large forward currents
and with slow rate of current decay all increase device
recovery time.
Where
Ebb
= power supply voltage
Vn(0) = 0 volts if the PFN employs a clamp diode or is
matched to the load
Tr
= time of resonant recharge and is usually equal
to
Lc
Cn
1
PRF
= value of charging inductance
= value of total PFN capacity
For a given radar pulse modulator design, the values of
power supply voltage, time of resonant recharge, charging
choke inductance, and PFN capacitance are established. If
the time (t) represents the recovery time of the SCR being
used as the discharge switch, ic then represents the
minimum value of holding current required by the SCR to
prevent power supply lock−on. Conversely, if the modulator design is about an existing SCR where holding current,
recovery time, and forward breakover voltage are known,
the charge parameters can be derived by rewriting the
above formula as follows:
T r2(recovery time)
cos
V BO V n(0)
2L c Cn
iH Tr
Lc
C n sin
2L c Cn
HOLDING CURRENT
One of the anomalies that exist in the design of a pulse
SCR is the requirement for a high holding current. This
need can be determined by examining the isolation
component that disconnects the power supply from the
discharge circuit during the time that PFN energy is being
transferred to the transmitter and during the recovery time
of the discharge switch. An inductance resonating with
the PFN capacitance at twice the time of recharge is
normally used for power supply isolation. Resonant
charging restricts the initial flow of current from the
power supply, thereby maximizing the time at which
power supply current flow will exceed the holding current
of the SCR. If the PFN recharge current from the power
supply exceeds the holding current of the SCR before it
has recovered, the SCR will again conduct without the
application of a trigger pulse. As a result continuous
conduction occurs from the power supply through the low
impedance path of the charging choke and on switch. This
lock−on condition can completely disable the equipment
employing the SCR switch.
The charging current passed by the inductance is given
as (the PFN inductance is considered negligible):
The designer may find that for the chosen SCR the
desired characteristics of modulator pulse width and pulse
repetition frequency are not obtainable.
One means of increasing the effective holding current
of an SCR is for the semiconductor to exhibit some
turn−off gain characteristic for the residual current flow at
the end of the modulator pulse. The circuit designer then
can provide turn−off base current, making the SCR more
effective as a pulse circuit element.
THE SCR AS A UNIDIRECTIONAL SWITCH
When triggered to its on state, the SCR, like the
hydrogen thyratron, is capable of conducting current in
one direction. A load short circuit could result in an
inverse voltage across the SCR due to the reflection of
voltage from the pulse forming network. The circuit
designer may wish to provide an intentional load−to−PFN
mismatch such that some inverse voltage is generated
across the SCR to enhance its turn−off characteristics.
Nevertheless, since the normal circuit application is
unidirectional, the semiconductor device designer could
take advantage of this fact in restricting the inverse−voltage rating that the SCR must withstand. The circuit
designer, in turn, can accommodate this lack of peak−
inverse−voltage rating by use of a suitable diode clamp
across the PFN or across the SCR.
Tr2t
cos
E bb V n(0)
2L c Cn
ic(t) Tr Lc
C n sin
2Lc Cn
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SCRs TESTS FOR PULSE CIRCUIT
APPLICATION
To measure turn−on time using a Tektronix 545
oscilloscope (or equivalent) with a dual trace type CA
plug−in, connect probes of Channels A and B to Test
Points A and B. Place the Mode selector switch in the
Added Algebraically position and the Channel B Polarity
switch in the Inverted position. Adjust the HR212A pulse
generator to give a positive pulse 1 μs wide (100 pps) as
viewed at Test Point A. Adjust the amplitude of the
“added” voltage across the 100−ohm base resistor for the
specified pulse gate current (200 mA in this example).
Switch the Mode selector knob to the alternate position.
Connect Channel A to Test Point D. Leave the oscilloscope probe, Channel B, at Test Point B, thereby
displaying the input trigger waveform. Measure the time
between the 50 percent voltage amplitudes of the two
waveforms. This is the Turn−On Time (tD + tR).
To measure turn−on time versus temperature, place the
device to be tested on a suitable heat sink and place the
assembly in a temperature chamber. Stabilize the chamber
at minimum rated (cold) temperature. Repeat the above
measurements. Raise the chamber temperature to maximum rated (hot) temperature and stabilize. Repeat the
measurements above.
The suitability for pulse circuit applications of SCRs
not specifically characterized for such purposes can be
determined from measurements carried out with relatively
simple test circuits under controlled conditions. Applicable test circuits and procedures are outlined in the
following section.
FORWARD BLOCKING VOLTAGE AND LEAKAGE
CURRENT
Mount the SCRs to a heat sink and connect the units to
be tested as shown in Figure 5.21. Place the assembly in
an oven and stabilize at maximum SCR rated temperature. Turn on the power supply and raise the voltage to
rated VBO. Allow units to remain with the voltage applied
for minimum of four hours. At the end of the temperature
soak, determine if any units exhibit thermal runaway by
checking for blown fuses (without removing the power).
Reject any units which have blown circuit fuses. The
forward leakage current, ILF, of the remaining units may
be calculated after measuring the voltage VL, across
resistor R2. Any units with a leakage current greater than
manufacturer ’s rating should be rejected.
+
REGULATED
POWER
SUPPLY
−
VL
R2
1/16 A
ANODE
GATE CATHODE
ADDITIONAL UNITS
MAY BE
CONNECTED IN
PARALLEL
R1
Figure 5.20. Vertical Set to 4 cm, Horizontal 0.2 μs/cm.
Detected RF Magnetron Pulse
Figure 5.21. Test Setup for SCR Forward Blocking
Voltage and Leakage Current Measurements
TURN−ON TIME, VARIATION AND ON IMPEDANCE
This circuit assumes that the pulse gate current required
to switch a given modulator load current is specified by
the manufacturer or that the designer is able to specify the
operating conditions. Typical operating values might be:
Time of trigger pulse t = 1 μs
Pulse gate current IG = 200 mA
Forward blocking voltage VBO = 400 V
Load current ILoad = 30 A
RESISTOR R1 IS USED ONLY IF MANUFACTURER CALLS FOR
BIAS RESISTOR BETWEEN GATE AND CATHODE. RESISTOR
R2 CAN HAVE ANY SMALL VALUE WHICH, WHEN MULTIPLIED
BY MAXIMUM ALLOWABLE LEAKAGE CURRENT, WILL
PROVIDE A CONVENIENT READING OF VOLTAGE VL.
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To measure the turn−on impedance for the specified
current load, the on impedance can be measured as an
SCR forward voltage drop. The point in time of
measurement shall be half the output pulse width. For a
1 μs output pulse, the measurement procedure would be:
Connect the oscilloscope probe, Channel B, to Point D
shown in Figure 5.22. Use the oscilloscope controls
Time/CM and Multiplier to a setting of 0.5 μs per
centimeter or faster. With the Amplitude Control set to
view 100 volts per centimeter (to prevent amplifier
overloading) measure the amplitude of the voltage drop,
VF, across the SCR 0.5 μs after the PFN voltage waveform
has dropped to half amplitude. It may be necessary to
check ground reference several times during this test to
provide the needed accuracy of measurement.
E = VBO
VBO
V BO
2
1
2
mA Von
0V
IC = AS SPECIFIED
t = AS SPECIFIED
B
A
1:1
HP
212A
100
VBO V
D
zO = R
V BO
V(A B)
R1
100 k W
Any unit which turns on but does not turn off has a
holding current of less than
100
k
t = AS SPECIFIED
100 kW
C
R
51
To measure holding current, connect the SCRs under
test as illustrated in Figure 5.23. Place SCRs in oven and
stabilize at maximum expected operating temperature.
View the waveform across R1 by connecting the oscilloscope probe (Tektronix 2465) Channel A to Point A, and
Channel B to Point B. Place the Mode Selector switch in
the Added Algebraically position. Place the Polarity
swich of Channel B in the Inverted position. Adjust both
Volts/CM switches to the same scale factor, making sure
that each Variable knob is in its Calibrated position.
Adjust pulse generator for a positive pulse, 1 μs wide, and
1,000 pps pulse repetition frequency. Adjust power supply
voltage to rated VBO. Adjust input pulse amplitude until
unit fully triggers. Measure amplitude of voltage drop
across R1, V(A − B), and calculate holding current in mA
from the equation
V BO
2:1
The approximate voltage setting to view the amplitude
of the holding current will be 10 or 20 volts per
centimeter. The approximate sweep speed will be 2 to
5 μs per centimeter. These settings will, of course, vary,
depending upon the holding current of the unit under test.
SCR recovery time is greatly dependent upon the circuit
in which the device is used. However, any test of SCR
recovery time should suffice to compare devices of
various manufacturers, as long as the test procedure is
standardized. Further evaluation of the selected devices
could be made in an actual modulator circuit tester
wherein techniques conducive to SCR turn−off are used.
The circuit setup shown in Figures 5.24 and 5.25 can be
employed for such tests. A slight load to PFN mismatch is
called for to generate an inverse voltage across the SCR at
the termination of the output pulse. An SCR gate turn−off
pulse is used. The recharge component is a charging
choke, providing optimized conditions of reapplied
voltage to the PFN (and across the SCR). Adequate heat
sinking of the SCR should be provided.
LOAD
WHERE ILOAD =
AS SPECIFIED
Figure 5.22. Suggested Test Circuit for SCR “On”
Measurements
HOLDING CURRENT
The SCR holding current can be measured with or
without a gate turn−off current, according to the position
of switch S2. The ON Semiconductor Trigger Pulse
Generator is a transistor circuit capable of generating a
1.5 μs turn−on pulse followed by a variable−duration
turn−off pulse. Measurements should be made at the
maximum expected temperature of operation. Resistor R1
should be chosen to allow an initial magnitude of current
flow at the device pulse current rating.
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HARRISON
800 A
P.S.
+12 −12
B
2W
100k
A
R1
TIME AT WHICH TO MEASURE IN
+
R3
S1A
HP212
PULSE
GEN.
ON
SEMI−
CONDUCTOR
S2 TRIGGER
PULSE
GEN
ANODE
C1
7500 fd.
S1B
GATE
REGULATED
POWER
SUPPLY
CATHODE
R2
IH
VOLTAGE LEVEL FROM
WHICH TO CALCULATE
HOLDING CURRENT
R4
51 Ω
−
NOTE: ADDITIONAL UNITS MAY BE TESTED BY SWITCHING THE
ANODE AND GATE CONNECTIONS TO SIMILARLY
MOUNTED SCRs. SHORT LEAD LENGTHS ARE DESIRABLE.
Figure 5.23. Test Setup for Measuring Holding Current
REGULATED
POWER
SUPPLY
CHARGING
CHOKE
B
HARRISON
800 A
+12 −12
HOLD OFF
DIODE
PFN
A
HP212A
PULSE
GEN
ON
SEMI−
CONDUCTOR
TRIGGER
PULSE
GEN
zO RLOAD
ANODE
C
GATE
CATHODE
R
Figure 5.24. Modulator Circuit for SCR Tests
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RLOAD
CHARGE
IMPEDANCE
POWER
SUPPLY
LOAD
ENERGY
STORE
DISC
SWITCH
BLOCK DIAGRAM;
CHARGING CHOKE
HOLD OFF DIODE
PULSE TRANSFORMER
PFN
LOAD
Es
TRIGGER
IN
SCR
SIMPLIFIED SCHEMATIC
Figure 5.25. Radar Modulator, Resonant Line Type
PARALLEL CONNECTED SCRs
be at least two or three times the IGT(MAX) specification
on the data sheet and ideally close to, but never
exceeding, the maximum specified gate power dissipation
or peak current. Adequate gate current is necessary for
rapid turn−on of all the parallel SCRs and to ensure
simultaneous turn−on without excessive current crowding
across any of the individual die. The rise time of the gate
drive pulse should be fast, ideally 100 ns. Each gate
should be driven from a good current source and through
its own resistor, even if transformer drive is used. Gate
pulse width requirements vary but should be of sufficient
width to ensure simultaneous turn−on and last well
beyond the turn−on delay of the slowest device, as well as
beyond the time required for latching of all devices.
Ideally, gate current would flow for the entire conduction
period to ensure latching under all operating conditions.
With low voltage switching, which includes conduction
angles near 180° and near zero degrees, the gate drive
requirements can be more critical and special emphasis
may be required of gate pulse amplitude and width.
When an application requires current capability in
excess of a single economical SCR, it can be worthwhile
to consider paralleling two or more devices. To help
determine if two or more SCRs in parallel are more cost
effective than one high current SCR, some of the
advantages and disadvantages are listed for parallel
devices.
Advantages
1. Less expensive to purchase
2. Less expensive to mount
3. Less expensive to replace, in case of failure
4. Ease of mounting
5. Ease of isolation from sink
Disadvantages
1. Increased SCR count
2. Selected or matched devices
3. Increased component count
4. Greater R & D effort
PARAMETER MATCHING
There are several factors to keep in mind in paralleling
and many are pertinent for single SCR operations as well.
For reliable current sharing with parallel SCRs, there
are certain device parameters that should be matched or
held within close tolerances. The degree of matching
required varies and can be affected by type of load
(resistive, inductive, incandescent lamp or phase controlled loads) being switched.
GATE DRIVE
The required gate current (IGT) amplitude can vary
greatly and can depend upon SCR type and load being
switched. As a general rule for parallel SCRs, IGT should
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turned on, probably causing failure from over−current and
excessive junction temperature.
The most common device parameters that can effect
current sharing are:
Table 5.5. MCR12D Turn−On Delay, Rise Time and
Minimum Forward Anode Voltage For Turn−On
1. td — turn−on delay time
2. tr — turn−on rise time of anode current
3. VA(MIN) — minimum anode voltage at which device
will turn on
4. Static on−state voltage and current
5. IL — Latching current
Device
Turn−On Delay and Rise Time
Off−State Voltage = 8 V Peak
RL = 10 Ohms, IA 6.5 A Peak
IG = 100 mA (PW = 100 μs)
Conduction Angle 90 Degrees
The four parameters shown in Table 5.6 were measured
with a curve tracer and are:
IL, latching current; VTM, on−state voltage; IGT and
VGT, minimum gate current and voltage for turn on.
Of the four parameters, IL and VTM can greatly affect
current sharing.
The latching current of each SCR is important at
turn−on to ensure each device turns on and will stay on for
the entire conduction period. On−state voltage determines
how well the SCRs share current when cathode ballasting
is not used.
Table 5.5 gives turn−on delay time (td) and turn−on rise
time (tr) of the anode−cathode voltage and the minimum
forward anode voltage for turn−on. These parameters
were measured in the circuits shown in Figures 5.28 and
5.29. One SCR at a time was used in the circuit shown in
Figure 5.28.
Turn−on delay on twenty−five SCRs was measured
(only ten are shown in Table 5.5) and they could be from
one or more production lots. The variation in td was slight
and ranged from 35 to 44 ns but could vary considerably
on other production lots and this possible variation in td
would have to be considered in a parallel application.
Waveforms for minimum forward anode voltage for
turn−on are shown in Figure 5.26. The trailing edge of the
gate current pulse is phase delayed (R3) so that the SCR is
not turned on. The width of the gate current pulse is now
increased (R5) until the SCR turns on and the forward
anode voltage switches to the on−state at about 0.73 V.
This is the minimum voltage at which this SCR will turn
on with the circuit conditions shown in Figure 5.28.
For dynamic turn−on current sharing, td, tr and VA(MIN)
are very important. As an example, with a high wattage
incandescent lamp load, it is very important that the
inrush current of the cold filament be equally shared by
the parallel SCRs. The minimum anode voltage at which a
device turns on is also very important. If one of the parallel
devices turns on before the other devices and its on−state
voltage is lower than the required minimum anode
voltage for turn−on of the unfired devices, they therefore
cannot turn on. This would overload the device which
1
2
3
4
5
6
7
8
9
10
Minimum Anode
Voltage For
Turn−On Off−State
Voltage = 4 V Peak
RL = 0.5 Ohm
IA = 5A
IG = 100 mA
td(ns)
tr(μs)
(Volts)
35
38
45
44
44
43
38
38
38
37
0.80
0.95
1
1
0.90
0.85
1.30
1.25
1
0.82
0.70
0.81
0.75
0.75
0.75
0.75
0.75
0.70
0.75
0.70
OFF−STATE
ANODE−CATHODE
VOLTAGE 0.2 V/Div
ON−STATE
IG = 50
1 mA/Div
0
0
100 μs/Div
Figure 5.26. Minimum Anode Voltage For Turn−On
Off−State Voltage = 4 V Peak, RL = 0.5 Ohm,
IA ≈ 5 A, IG = 75 mA
Turn−off time — tq is important in higher frequency
applications which require the SCR to recover from the
forward conduction period and be able to block the next
cycle of forward voltage. Thus, tq matching for high
frequency operation can be as important as td, tr and
VA(MIN) matching for equal turn−on current sharing.
Due to the variable in tq measurement, no further
attempt will be made here to discuss this parameter and
the reader is referred to Application Note AN914.
The need for on−state matching of current and voltage
is important, especially in unforced current sharing
circuits.
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UNFORCED CURRENT SHARING
its share of current (Figure 5.29) with RK equal zero. As
RK increases, device 2 takes a greater share of the total
current and with RK around 0.25 ohm, the four SCRs are
sharing peak current quite well. The value of RK depends
on how close the on−state voltage is matched on the SCRs
and the degree of current sharing desired, as well as the
permissible power dissipation in RK.
When operating parallel SCRs without forced current
sharing, such as without cathode ballasting using resistors
or inductors, it is very important that the device
parameters be closely matched. This includes td, tr,
minimum forward anode voltage for turn−on and on−state
voltage matching. The degree of matching determines the
success of the circuit.
In circuits without ballasting, it is especially important
that physical layout, mounting of devices and resistance
paths be identical for good current sharing, even with
on−state matched devices.
Figure 5.27 shows how anode current can vary on
devices closely matched for on−state voltage (1, 3 and 4)
and a mismatched device (2). Without resistance ballasting, the matched devices share peak current within one
ampere and device 2 is passing only nine amps, seven
amps lower than device 1. Table 5.6 shows the degree of
match or mismatch of VTM of the four SCRs.
With unforced current sharing (RK = 0), there was a
greater tendency for one device (1) to turn−on, preventing
the others from turning on when low anode switching
voltage ( 10 V rms) was tried. Table 5.5 shows that the
minimum anode voltage for turn−on is from 7 to 14%
lower for device 1 than on 2, 3 and 4. Also, device 1
turn−on delay is 35 ns versus 38, 45 and 44 ns for devices
2, 3 and 4.
The tendency for device 1 to turn on, preventing the
other three from turning on, is most probably due to its
lower minimum anode voltage requirement and shorter
turn on delay. The remedy would be closer matching of
the minimum anode voltage for turn−on and driving the
gates hard (but less than the gate power specifications)
and increasing the width of the gate current pulse.
IA(pk) , PEAK ANODE CURRENT (AMPS)
17
#3
15
13
#4
11
#2
IG = 400 mA
PW = 400 μs
OFF−STATE VOLTAGE = 26 V (rms)
INDUCTIVE LOAD
CONDUCTION ANGLE = 120°
9
7
SCR #1
0
50
100
150
200
RK, CATHODE RESISTORS (MILLIOHMS)
250
Figure 5.27. Effects Of Cathode Resistor On Anode
Current Sharing
Table 5.6. MCR12D Parameters Measured On Curve
Tracer, TC = 25°C
Device #
IL, Latching
Current
VD = 12 Vdc
IG = 100 mA
VTM, On−State
Voltage
IA = 15 A
PW = 300 μs
1
2
3
4
5
6
7
8
9
10
13 mA
27
28
23
23
23
18
19
19
16
1.25 V
1.41
1.26
1.26
1.28
1.26
1.25
1.25
1.25
1.25
FORCED CURRENT SHARING
Cathode ballast elements can be used to help ensure
good static on−state current sharing. Either inductors or
resistors can be used and each has advantages and
disadvantages. This section discuses resistive ballasting,
but it should be kept in mind that the inductor method is
usually better suited for the higher current levels.
Although they are more expensive and difficult to design,
there is less power loss with inductor ballasting as well as
other benefits.
The degree of peak current sharing is shown in
Figure 5.27 for four parallel MCR12D SCRs using
cathode resistor ballasting with an inductive anode load.
With devices 1, 3 and 4, on−state voltage is matched
within 10 mV at an anode current of 15 A (See Table 5.6)
and are within 1A of each other in Figure 5.27, with
cathode resistance (RK) equal to zero. As RK increases,
the current sharing becomes even closer. The unmatched
device 2, with a VTM of 1.41 V (Table 5.6), is not carrying
Minimum Gate
Current & Voltage
for Turn−On
VD = 12 Vdc,
RL = 140 Ω
IGT
VGT
5.6 mA
8.8
12
9.6
9.4
9.6
7.1
7
8.4
6.9
0.615 V
0.679
0.658
0.649
0.659
0.645
0.690
0.687
0.694
0.679
LINE SYNCHRONIZED DRIVE CIRCUIT
Gate drive for phase control of the four parallel SCRs is
accomplished with one complementary MOS hex gate,
MC14572, and two bipolar transistors (Figure 5.28). This
adjustable line−synchronized driver permits SCR conduction from near zero to 180 degrees. A Schmitt trigger
clocks a delay monostable multivibrator that is followed
by a pulse−width monostable multivibrator.
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Line synchronization is achieved through the half−
wave section of the secondary winding of the full−wave,
center−tapped transformer (A). This winding also supplies
power to the circuit through rectifiers D1 and D2.
The full−wave signal is clipped by diode D5, referenced
to a + 15 volt supply, so that the input limit of the CMOS
chip is not exceeded. The waveform is then shaped by the
Schmitt trigger, which is composed of inverters U1 −a and
U1 −b. A fast switching output signal B results.
The positive−going edge of this pulse is differentiated
by the capacitive−resistive network of C1 and R2 and
triggers the delay multivibrator that is composed of U1 −c
and U1 −d. As a result, the normally high output is
switched low. The trailing edge of this pulse (C) then
triggers the following multivibrator, which is composed
of NAND gate U1 −e and inverter U1 −f. The positive going
output pulse (waveform D) of this multivibrator, whose
width is set by potentiometer R6, turns on transistors Q1
and Q2, which drives the gates of the four SCRs.
Transistor Q2 supplies about 400 mA drive current to each
gate through 100 ohm resistors and has a rise time of
100 ns.
D1
100 Ω, 250
1 W μF
D2
+ 15 V
1N5352
5 V, 5 W
R1
220 kΩ
25 V
D5
1N914
TRIAD
F90X
A
D3 1N914 1 kΩ
FULL−
WAVE
S1
120 V
60 Hz
D4
22 kΩ
C1
0.01
μF
U1 − b
3
1
2
4
B
0 kΩ
R5
100 kΩ
15
14
U1 −−e
6
7
R2
100
kΩ
SCHMITT TRIGGER
HALF
−
WAVE
1N914
5.30(a)
A 15 V
0
15 V
B
0
15 V
C
0
15 V
D
0
U1 − a
+ 15 V
R3
1 mΩ
U1
150
kΩ
R4
5
9
0.01
μF
10
U1−d
0.7 ms τ1 6 rms
DELAY MULTIVIBRATOR
0.01
μF
+ 15 V
0.01 μF
13
12
16
U1 − f
D
8
4.7 kΩ
0.00110 k
τ1
R6
25 kΩ
11
30 μs τ2 200 μs
PULSE−WIDTH
MULTIVIBRATOR
+ 40 V
10 k
Q2
MJE253
TIP122
0.005
10 k
τ2
1k
TO GATES
RESISTORS
5.30(b)
Figure 5.28. Line−Synchronized Gate Driver
PARALLEL SCR CIRCUIT
The inductive load consisted of four filter chokes in
parallel (Stancor #C−2688 with each rated at 10 mH,
12.5 Adc and 0.11 ohm).
For good current sharing with parallel SCRs, symmetry
in layout and mounting is of primary importance. The
four SCRs were mounted on a natural finish aluminum
heat sink and torqued to specification which is 8 inch
pounds. Cathode leads and wiring were identical, and
when used, the cathode resistors RK were matched within
1%. An RC snubber network (R7 and C2) was connected
across the anodes−cathodes to slow down the rate−of−rise
of the off−state voltage, preventing unwanted turn−on.
The four SCRs are MCR12Ds, housed in the TO−220
package, rated at 12 A rms, 50 V and are shown
schematically in Figure 5.29. Due to line power limitations, it was decided to use a voltage step down
transformer and not try working directly from the 120 V
line. Also, line isolation was desirable in an experiment of
this type.
The step down transformer ratings were 120 V rms
primary, 26 V rms secondary, rated at 100 A, and was used
with a variable transformer for anode voltage adjustment.
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LOAD: FOUR STANCOR FILTER CHOKES (#C−2688) IN PARALLEL
EACH RATED AT: 10 mH @ 12.5 Adc AND 0.11 OHMS
ALL ANODES COMMON TO HEAT SINK
Q3
26 V rms
100
120 V rms
60 Hz
Q4
100
1k
100
1k
RK
Q6
Q5
R7
100
SNUBBER
100
1k
1k
RK
RK
RK
0.25
C2
Q3−Q6, MCR12D
Figure 5.29. Parallel Thyristors
CHARACTERIZING RFI SUPPRESSION IN
THYRISTOR CIRCUITS
A common example of the connection of 5.30(a) is the
wall mounted light dimmer controlling a ceiling mounted
lamp. A motorized appliance with a built−in control such
as a food mixer is an example of the connection shown in
5.30(b).
Figure 5.30(a) may be re−drawn as shown in
Figure 5.31, illustrating the complete circuit for RF
energy. The switch in the control box represents the
thyristor, shown in its blocking state. In phase control
operation, this switch is open at the beginning of each
half cycle of the power line alternations. After a delay
determined by the remainder of the control circuitry,
the switch is closed and remains that way until the
instantaneous current drops to zero. This switch is the
source from which the RF energy flows down the power
lines and through the various capacitors to ground.
In order to understand the measures for suppression of
EMI, characteristics of the interference must be explored
first. To have interference at all, we must have a transmitter,
or creator of interference, and a receiver, a device affected
by the interference. Neither the transmitter nor the receiver
need be related in any way to those circuits commonly
referred to as radio−frequency circuits. Common transmitters are opening and closing of a switch or relay contacts,
electric motors with commutators, all forms of electric arcs,
and electronic circuits with rapidly changing voltages and
currents. Receivers are generally electronic circuits, both
low and high impedance which are sensitive to pulse or high
frequency energy. Often the very circuits creating the
interference are sensitive to similar interference from other
circuits nearby or on the same power line.
EMI can generally be separated into two categories —
radiated and conducted. Radiated interference travels by
way of electro−magnetic waves just as desirable RF
energy does. Conducted interference travels on power,
communications, or control wires. Although this separation and nomenclature might seem to indicate two neat
little packages, independently controllable, such is not the
case. The two are very often interdependent such that in
some cases control of one form may completely eliminate
the other. In any case, both interference forms must be
considered when interference elimination steps are taken.
Phase control circuits using thyristors (SCRs, triacs,
etc.) for controlling motor speed or resistive lighting and
heating loads are particularly offensive in creating
interference. They can completely obliterate most stations
on any AM radio nearby and will play havoc with another
control on the same power line. These controls are
generally connected in one of the two ways shown in the
block diagrams of Figure 5.30.
CONTROL
LOAD
LINE
(a). Separately Mounted Control
CONTROL
LINE
LOAD
(b). Control and Load in the Same Enclosure
Figure 5.30. Block Diagram of Control Connections
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If the load is passive, such as a lamp or a motor which
does not generate interference, it may be considered as an
impedance bypassed with the wire−to−wire capacitance
of its leads. If it is another RF energy source, however,
such as a motor with a commutator, it must be treated
separately to reduce interference from that source. The
power supply may be considered as dc since the
interference pulse is extremely short (10 μs) compared to
the period of the power line frequency (16 ms for 60 Hz).
The inductance associated with the power source comes
from two separate phenomena. First is the leakage
impedance of the supply transformer, and second is the
self−inductance of the wires between the power line
transformer and the load.
One of the most difficult parameters to pin down in the
system is the effect of grounding. Most industrial and
commercial wiring and many homes use a grounded
conduit system which provides excellent shielding of
radiated energy emanating from the wiring. However, a
large number of homes are being wired with two to three
wire insulated cable without conduit. In three−wire
systems, one wire is grounded independently of the power
system even though one of the power lines is already
grounded. The capacitances to ground shown in
Figure 5.31 will be greatly affected by the type of
grounding used. Of course, in any home appliance,
filtering must be provided suitable for all three different
systems.
Before the switch in the control is closed, the system
is in a steady−state condition with the upper line of the
power line at the system voltage and the bottom line and
the load at ground potential. When the switch is closed,
the upper line potential instantaneously falls due to the
line and source inductance, then it rises back to its
original value as the line inductance is charged. While
the upper line is rising, the line from the control to the
load also rises in potential. The effect of both of these
lines increasing in potential together causes an electro−
static field change which radiates energy. In addition,
any other loads connected across the power lines at
point A, for example, would be affected by a temporary
loss of voltage created by the closing of the switch and
by the line and source inductance. This is a form of
conducted interference.
A second form of radiated interference is inductive
coupling in which the power line and ground form a
one−turn primary of an air core transformer. In this mode,
an unbalanced transient current flows down the power
lines with the difference current flowing to ground
through the various capacitive paths available. The
secondary is the radio antenna or the circuit being
affected. This type of interference is a problem only when
the receiver is within about one wavelength of the
transmitter at the offending frequency.
Radiated interference from the control circuit proper is
of little consequence due to several factors. The lead
lengths in general are so short compared to the wavelengths in question that they make extremely poor
antenna. In addition, most of these control circuits are
mounted in metal enclosures which provide shielding for
radiated energy generated within the control circuitry.
A steel box will absorb radiated energy at 150 kHz such
that any signal inside the box is reduced 12.9 dB per mil
of thickness of the box. In other words, a 1/16 inch thick
steel box will attenuate radiated interference by over 800
dB! A similar aluminum box will attenuate 1 dB per mil
or 62.5 dB total. Thus, even in an aluminum box, the
control circuitry will radiate very little energy.
Both forms of radiated interference which are a
problem are a result of conducted interference on the
power lines which is in turn caused by a rapid rise in
current. Thus, if this current rise is slowed, all forms of
interference will be reduced.
RFI SOLUTIONS
Since the switch in Figure 5.31, when it closes, provides
a very low impedance path, a capacitor in parallel with it
will show little benefit in slowing down the rise of
current. The capacitor will be charged to a voltage
determined by the circuit constants and the phase angle of
the line voltage just before the switch closes. When the
switch closes, the capacitor will discharge quickly, its
current limited only by its own resistance and the
resistance of the switch. However, a series inductor will
slow down the current rise in the load and thus reduce the
voltage transient on all lines. A capacitor connected as
shown in Figure 5.32 will also help slow down the current
rise since the inductor will now limit the current out of the
capacitor. Thus, the capacitor voltage will drop slowly
and correspondingly the load voltage will increase slowly.
Although this circuit will be effective in many cases,
the filter is unbalanced, providing an RF current path
through the capacitances to ground. It has, therefore, been
found advantageous to divide the inductor into two parts
and to put half in each line to the control. Figure 5.33
illustrates this circuit showing the polarity marks of two
coils which are wound on the same core.
A capacitor at point A will help reduce interference
further. This circuit is particularly effective when used
with the connection of Figure 5.30(b) where the load is
not always on the grounded side of the power line. In this
case, the two halves of the inductor would be located in
the power line leads, between the controlled circuit and
the power source.
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to line transients. The value of tr may be calculated by
dividing the peak current anticipated by the allowable
rate of current rise.
Ferrite core inductors have proved to be the most
practical physical configuration. Most ferrites are effective; those with highest permeability and saturation flux
density are preferred. Those specifically designed as high
frequency types are not necessarily desirable.
Laminated iron cores may also be used; however, they
require a capacitor at point A in Figure 5.33 to be at all
effective. At these switching speeds, the iron requires
considerable current in the windings before any flux
change can take place. We have found currents rising to
half their peak value in less than one μs before the
inductance begins to slow down the rise. The capacitor
supplies this current for the short period without dropping
in voltage, thus eliminating the pulse on the power line.
Once a core material has been selected, wire size is the
next decision in the design problems. Due to the small
number of turns involved (generally a single layer)
smaller sizes than normally used in transformers may be
chosen safely. Generally, 500 to 800 circular mills per
ampere is acceptable, depending on the enclosure of the
filter and the maximum ambient temperature expected.
An idea of the size of the core needed may be
determined from the equation:
A
CONTROL
LOAD
Figure 5.31. RF Circuit for Figure 5.30(a)
0.1 μF
100 μH
CONTROL
10 A TRIAC
8A
LOAD
(1) AcA w Figure 5.32. One Possible EMI Reduction Circuit
26 Awire E rms tr
B MAX
where:
Ac = the effective cross−sectional area of the core
in in2
Aw = available core window area in in2
Awire = wire cross section in circular mils
BMAX = core saturation flux density in gauss
tr = allowable current rise time in seconds
Erms = line voltage
Where the control circuit is sensitive to fast rising line
transients, a capacitor at point B will do much to eliminate
this problem. The capacitor must charge through the
impedance of the inductor, thus limiting the rate of
voltage change (dv/dt) applied to the thyristor while it is
in the blocking state.
DESIGN CRITERIA
(A factor of 3 has been included in this equation to allow
for winding space factor.) Once a tentative core selection
has been made, the number of turns required may be
found from the equation:
Design equations for the split inductor have been
developed based on parameters which should be known
before attempting a design. The most difficult to
determine is tr, the minimum allowable current rise
time which will not cause objectionable interference.
The value of this parameter must be determined
empirically in each situation if complete interference
reduction is needed. ON Semiconductor has conducted
extensive tests using an AM radio as a receiver and a
600 Watt thyristor lamp dimmer as a transmitter. A rate
of about 0.35 Amp per μs seems to be effective in
eliminating objectionable interference as well as
materially reducing false triggering of the thyristor due
(2)
N
11 Erms t r 10 6
B MAXAc
where:
N = the total number of turns on the core
The next step is to check how well the required number of
turns will fit onto the core. If the fit is satisfactory, the
core design is complete; if not, some trade−offs will have
to be made.
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240 μH
A
120 Vac
B
As was previously mentioned, a current rise rate of
about 0.35 ampere per μs has been found to be acceptable
for interference problems with ac−dc radios in most
wiring situations. With 5 amperes rms, 7 amperes peak,
CONTROL
10 A TRIAC
240 μH
5A
LOAD
tr 7 20 ms
0.35
Then the equation (1):
Figure 5.33. Split Inductor Circuit
In most cases, the inductor as designed at this point will
have far too much inductance. It will support the entire
peak line voltage for the time selected as tr and will then
saturate quickly, giving much too fast a current rise. The
required inductance should be calculated from the
allowable rise time and load resistance, making the rise
time equal to two time constants. Thus:
(3)
2L t
r
R
or
L
AcA w 26 2580 120 20 10
3800 gauss
Ig 0.044
Core part number 1F30 of the same company in a U−1
configuration has an AcAw product of 0.0386, which
should be close enough.
R tr
2
6 10 6
N 10.93 120 20 10
42 turns
3800 0.137
Paper or other insulating material should be inserted
between the core halves to obtain the required inductance
by the equation:
(4)
6
Two coils of 21 turns each should be wound on either one
or two legs and be connected as shown in Figure 5.33.
The required inductance of the coil is found from
equation (3).
3.19 N 2 Ac 10 8 Ic
m
L
where:
Ig = total length of air gap in inches
μ = effective ac permeability of the core material at
the power line frequency
Ic = effective magnetic path length of the core
in inches
Ac = effective cross sectional area of the core in
square inches
L = inductance in henries
L
Erated tr
R tr
120 20 10 –6 240 10–6
2
5
2
I rated 2
L 240 mH
To obtain this inductance, the air gap should be
2
–8
Ig 3.1942 0.13710 – 3.33 0.0321–0.00175
–6
1900
24010
Ig 0.03035
DESIGN EXAMPLE
Consider a 600 watt, 120 Volt lamp dimmer using an
ON Semiconductor 2N6348A triac. Line current is 600 =
120
5 amperes. #16 wire will provide about 516 circular mils
per ampere.
For core material, type 3C5 of Ferroxcube Corporation
of America, Saugerties, New York, has a high Bmax and μ.
The company specifies BMAX = 3800 gauss and μ = 1900
for material.
Thus, 15 mils of insulating material in each leg will
provide the necessary inductance.
If a problem still exists with false triggering of the
thyristor due to conducted interference, a capacitor at
point B in Figure 5.33 will probably remedy the situation.
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SECTION 6
APPLICATIONS
Edited and Updated
PORTION OF WAVEFORM
APPLIED TO LOAD
Because they are reliable solid state switches, thyristors
have many applications, especially as controls.
One of the most common uses for thyristors is to control
ac loads such as electric motors. This can be done either by
controlling the part of each ac cycle when the circuit
conducts current (phase control) or by controlling the
number of cycles per time period when current is conducted (cycle control).
In addition, thyristors can serve as the basis of relaxation
oscillators for timers and other applications. Most of the
devices covered in this book have control applications.
α
α
Figure 6.1. Phase Control of AC Waveform
PHASE CONTROL WITH THYRISTORS
The most common method of electronic ac power
control is called phase control. Figure 6.1 illustrates this
concept. During the first portion of each half-cycle of the
ac sine wave, an electronic switch is opened to prevent the
current flow. At some specific phase angle, α, this switch is
closed to allow the full line voltage to be applied to the load
for the remainder of that half-cycle. Varying α will control
the portion of the total sine wave that is applied to the load
(shaded area), and thereby regulate the power flow to the
load.
The simplest circuit for accomplishing phase control is
shown in Figure 6.2. The electronic switch in this case is a
triac (Q) which can be turned on by a small current pulse to
its gate. The TRIAC turns off automatically when the
current through it passes through zero. In the circuit shown,
capacitor CT is charged during each half-cycle by the
current flowing through resistor RT and the load. The fact
that the load is in series with RT during this portion of the
cycle is of little consequence since the resistance of RT is
many times greater than that of the load. When the voltage
across CT reaches the breakdown voltage of the DIAC
bilateral trigger (D), the energy stored in capacitor CT is
released. This energy produces a current pulse in the
DIAC, which flows through the gate of the TRIAC and
turns it on. Since both the DIAC and the TRIAC are
bidirectional devices, the values of RT and CT will
determine the phase angle at which the TRIAC will be
triggered in both the positive and negative half-cycles of
the ac sine wave.
LOAD
RT
Q
AC LINE
VOLTAGE
D
CT
Figure 6.2. Simplest Circuit for Phase Control
α = 150°
α = 90°
α = 90°
α = 150°
APPLIED SINE WAVE
Figure 6.3. Waveforms of Capacitor Voltage
at Two Phase Angles
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VR
The waveform of the voltage across the capacitor for two
typical control conditions (α = 90° and 150°) is shown in
Figure 6.3. If a silicon controlled rectifier is used in this
circuit in place of the TRIAC, only one half-cycle of the
waveform will be controlled. The other half-cycle will be
blocked, resulting in a pulsing dc output whose average
value can be varied by adjusting RT.
3/4 VR
TYPICAL FAN
LOAD
SPEED
VR = FULL RATED VOLTAGE
1/2 VR
CONSTANT
TORQUE LOAD
1/4 VR
CONTROL OF INDUCTION MOTORS
TORQUE
Shaded-pole motors driving low-starting-torque loads
such as fans and blowers may readily be controlled using
any of the previously described full-wave circuits. One
needs only to substitute the winding of the shaded-pole
motor for the load resistor shown in the circuit diagrams.
Constant-torque loads or high-starting-torque loads are
difficult, if not impossible, to control using the voltage
controls described here. Figure 6.4 shows the effect of
varying voltage on the speed-torque curve of a typical
shaded-pole motor. A typical fan-load curve and a
constant-torque-load curve have been superimposed upon
this graph. It is not difficult to see that the torque developed
by the motor is equal to the load torque at two different
points on the constant-torque-load curve, giving two points
of equilibrium and thus an ambiguity to the speed control.
The equilibrium point at the lower speed is a condition of
high motor current because of low counter EMF and would
result in burnout of the motor winding if the motor were
left in this condition for any length of time. By contrast, the
fan speed-torque curve crosses each of the motor speedtorque curve crosses each of the motor speed-torque curves
at only one point, therefore causing no ambiguities. In
addition, the low-speed point is one of low voltage well
within the motor winding’s current-carrying capabilities.
Permanent-split-capacitor motors can also be controlled
by any of these circuits, but more effective control is
achieved if the motor is connected as shown in Figure 6.5.
Here only the main winding is controlled and the capacitor
winding is continuously connected to the entire ac line
voltage. This connection maintains the phase shift between
the windings, which is lost if the capacitor phase is also
controlled. Figure 6.6(a) shows the effect of voltage on the
speed-torque characteristics of this motor and a superimposed fan-load curve.
Figure 6.4. Characteristics of Shaded-Pole Motors
at Several Voltages
MOT
AC LINE
VOLTAGE
CONTROL
CIRCUIT
Figure 6.5. Connection Diagram for
Permanent-Split-Capacitor Motors
Not all induction motors of either the shaded-pole or
the permanent-split-capacitor types can be controlled
effectively using these techniques, even with the proper
loads. Motors designed for the highest efficiencies and,
therefore, low slip also have a very low starting torque
and may, under certain conditions, have a speed-torque
characteristic that could be crossed twice by a specific
fan-load speed-torque characteristic. Figure 6.6(b) shows
motor torque-speed characteristic curves upon which has
been superimposed the curve of a fan with high starting
torque. It is therefore desirable to use a motor whose
squirrel-cage rotor is designed for medium-to-high impedance levels and, therefore, has a high starting torque. The
slight loss in efficiency of such a motor at full rated speed
and load is a small price to pay for the advantage of speed
control prevents the TRIAC from turning on due to line
transients and inductive switching transients.
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TYPICAL FAN
LOAD
VR
3/4 VR
SPEED
SPEED
VR
3/4 VR
HIGH-STARTINGTORQUE FAN
LOAD
1/2 VR
1/2 VR
1/4 VR
1/4 VR
VR = FULL RATED VOLTAGE
TORQUE
TORQUE
(a). High-Starting-Torque Motor
(b). High-Efficiency Motor
Figure 6.6. Speed−Torque Curves for a Permanent−Split−Capacitor Motors at Various Applied Voltages
A unique circuit for use with capacitor-start motors in
explosive or highly corrosive atmospheres, in which the
arcing or the corrosion of switch contacts is severe and
undesirable, is shown in Figure 6.7. Resistor R1 is
connected in series with the main running winding and is
of such a resistance that the voltage drop under normal
full-load conditions is approximately 0.2 V peak. Since
starting currents on these motors are quite high, this peak
voltage drop will exceed 1 V during starting conditions,
triggering the TRIAC, which will cause current to flow
in the capacitor winding. When full speed is reached, the
current through the main winding will decrease to about
0.2 V, which is insufficient to trigger the TRIAC — thus
the capacitor winding will no longer be energized.
Resistor R2 and capacitor C2 form a dv/dt suppression
network; this prevents the TRIAC from turning on due to
line transients and inductive switching transients.
C1
MOT
AC LINE
VOLTAGE
C2
R2
R1
Figure 6.7. Circuit Diagram for Capacitor-Start Motor
CONTROL OF UNIVERSAL MOTORS
VR = FULL RATED VOLTAGE
Any of the half-wave or full-wave controls described
previously can be used to control universal motors. Nonfeedback, manual controls, such as those shown in
Figure 6.2, are simple and inexpensive, but they provide
very little torque at low speeds. A comparison of typical
speed-torque curves using a control of this type with those of
feedback control is shown in Figure 6.8.
These motors have some unique characteristics which
allow their speed to be controlled very easily and
efficiently with a feedback circuit such as that shown in
Figure 6.9. This circuit provides phase-controlled halfwave power to the motor; that is, on the negative
half-cycle, the SCR blocks current flow in the negative
direction causing the motor to be driven by a pulsating
direct current whose amplitude is dependent on the phase
control of the SCR.
VR
3/4 VR
1/2 VR
3/4 VR
SPEED
SPEED
VR
TORQUE
(A) NON-FEEDBACK CONTROL
1/2 VR
1/4 VR
TORQUE
(B) FEEDBACK CONTROL
Figure 6.8. Comparison of Feedback Control
with Non-Feedback Control
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The theory of operation of this control circuit is not at all
difficult to understand. Assuming that the motor has been
running, the voltage at point A in the circuit diagram must
be larger than the forward drop of Diode D1, the
gate-to-cathode drop of the SCR, and the EMF generated
by the residual MMF in the motor, to get sufficient current
flow to trigger the SCR.
The waveform at point A (VA) for one positive
half-cycle is shown in 6.9(b), along with the voltage
levels of the SCR gate (VSCR), the diode drop (VD), and
the motor-generated EMF (VM). The phase angle (α) at
which the SCR would trigger is shown by the vertical
dotted line. Should the motor for any reason speed up so
that the generated motor voltage would increase, the
trigger point would move upward and to the right along
the curve so that the SCR would trigger later in the
half-cycle and thus provide less power to the motor,
causing it to slow down again.
Similarly, if the motor speed decreased, the trigger point
would move to the left and down the curve, causing the
TRIAC to trigger earlier in the half-cycle providing more
power to the motor, thereby speeding it up.
Resistors R1, R2, and R3, along with diode D2 and
capacitor C1 form the ramp-generator section of the circuit.
Capacitor C1 is changed by the voltage divider R1, R2, and
R3 during the positive half-cycle. Diode D2 prevents
negative current flow during the negative half-cycle,
therefore C1 discharges through only R2 and R3 during
that half-cycle. Adjustment of R3 controls the amount by
which C1 discharges during the negative half-cycle.
Because the resistance of R1 is very much larger than the
ac impedance of capacitor C1, the voltage waveform on C1
approaches that of a perfect cosine wave with a dc
component. As potentiometer R2 is varied, both the dc and
the ac voltages are divided, giving a family of curves as
shown in 6.9(c).
The gain of the system, that is, the ratio of the change of
effective SCR output voltage to the change in generator
EMF, is considerably greater at low speed settings than it is
at high speed settings. This high gain coupled with a motor
with a very low residual EMF will cause a condition
sometimes known as cycle skipping. In this mode of
operation, the motor speed is controlled by skipping entire
cycles or groups of cycles, then triggering one or two
cycles early in the period to compensate for the loss in
speed. Loading the motor would eliminate this condition;
however, the undesirable sound and vibration of the motor
necessitate that this condition be eliminated. This can be
done in two ways.
The first method is used if the motor design is fixed and
cannot be changed. In this case, the impedance level of the
voltage divider R1, R2 and R3 can be lowered so that C1
will charge more rapidly, thus increasing the slope of the
ramp and lowering the system gain. The second method,
which will provide an overall benefit in improved circuit
performance, involves a redesign of the motor so that the
residual EMF becomes greater. In general, this means using
a lower grade of magnetic steel for the laminations. As a
matter of fact, some people have found that ordinary
cold-rolled steel used as rotor laminations makes a motor
ideally suited for this type of electronic control.
Another common problem encountered with this circuit
is that of thermal runaway. With the speed control set at
low or medium speed, at high ambient temperatures the
speed may increase uncontrollably to its maximum value.
This phenomenon is caused by an excessive impedance in
the voltage-divider string for the SCR being triggered. If
the voltage-divider current is too low, current will flow into
the gate of the SCR without turning it on, causing the
waveform at point A to be as shown in 6.9(d). The flat
portion of the waveform in the early part of the half-cycle
is caused by the SCR gate current loading the voltage
divider before the SCR is triggered. After the SCR is
triggered, diode D1 is back-biased and a load is no longer
on the voltage divider so that it jumps up to its unloaded
voltage. As the ambient temperature increases, the SCR
becomes more sensitive, thereby requiring less gate current
to trigger, and is triggered earlier in the half-cycle.This
early triggering causes increased current in the SCR,
thereby heating the junction still further and increasing still
further the sensitivity of the SCR until maximum speed has
been reached.
The solutions to this problem are the use of the most
sensitive SCR practical and a voltage divider network of
sufficiently low impedance. As a rough rule of thumb, the
average current through the voltage divider during the
positive half-cycle should be approximately three times the
current necessary to trigger the lowest-sensitivity (highest
gate current) SCR being used.
R1
A
C1
AC LINE
VOLTAGE
D1
R2
C2
R3
MOT
D2
Figure 6.9. (a). Speed-Control Scheme for
Universal Motors
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be short-circuited without causing danger. Many designers
have found it advantageous, therefore, to use 115 V motors
with this system and provide a switch to apply full-wave
voltage to the motor for high-speed operation. Figure 6.10
shows the proper connection for this switch. If one were to
simply short-circuit the SCR for full-speed operation, a
problem could arise. If the motor were operating at full
speed with the switch closed, and the switch were then
opened during the negative half-cycle, the current flowing
in the inductive field of the motor could then break down
the SCR in the negative direction and destroy the control.
With the circuit as shown, the energy stored in the field of
the motor is dissipated in the arc of the switch before the
SCR is connected into the circuit.
VA
VA
VD
VSCR
VM
α
PHASE
ANGLE
(b). Waveform for One Positive Half-Cycle of Circuit
VA
(R2)′
(R2)″
R2
α1
α2
α3
AC LINE VOLTAGE
VM
PHASE
ANGLE
(c). Voltage Waveform at Point “A” for Three Settings
of Potentiometer R2
CONTROL
CIRCUIT
MOT
TRIGGER
POINT
Figure 6.10. Switching Scheme for
Full-Wave Operation
UNLOADED
WAVEFORM
CONTROL OF PERMANENT-MAGNET MOTORS
As a result of recent developments in ceramic permanent-magnet materials that can be easily molded into
complex shapes at low cost, the permanent-magnet motor
has become increasingly attractive as an appliance component. Electronic control of this type of motor can be easily
achieved using techniques similar to those just described
for the universal motor. Figure 6.11 is a circuit diagram of
a control system that we have developed and tested
successfully to control permanent-magnet motors presently
being used in blenders. Potentiometer R3 and diode D1
form a dc charging path for capacitor C1; variable resistor
R1 and resistor R2 form an ac charging path which creates
the ramp voltage on the capacitor. Resistor R4 and diode
D2 serve to isolate the motor control circuit from the ramp
generator during the positive and negative half-cycles,
respectively.
ACTUAL
WAVEFORM
(d). Point “A” Voltage with Excessive Resistance R1
In addition to the type of steel used in the motor
laminations, consideration should also be given to the
design of motors used in this half-wave speed control.
Since the maximum rms voltage available to the motor
under half-wave conditions is 85 V, the motor should be
designed for use at that voltage to obtain maximum speed.
However, U.L. requirements state that semiconductor
devices used in appliance control systems must be able to
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must be used, or the line voltage must be full-wave
rectified using relatively high current rectifiers, or the
control must be limited to half-wave. The TRIAC eliminates all these difficulties. By using a TRIAC the part
count, package size, and cost can be reduced. Figure 6.13
shows a TRIAC motor speed control circuit that derives its
feedback from the load current and does not require
separate connections to the motor field and armature
windings. Therefore, this circuit can be conveniently built
into an appliance or used as a separate control.
The circuit operates as follows: When the TRIAC
conducts, the normal line voltage, less the drop across the
TRIAC and resistor R5, is applied to the motor. By
delaying the firing of the TRIAC until a later portion of the
cycle, the rms voltage applied to the motor is reduced and
its speed is reduced proportionally. The use of feedback
maintains torque at reduced speeds.
Diodes D1 through D4 form a bridge which applies
full-wave rectified voltage to the phase-control circuit. Phase control of the TRIAC is obtained by the
charging of capacitor C1 through resistors R2 and R3 from
the voltage level established by zener diode D5. When C1
charges to the firing voltage of PUT Q1, the TRIAC
triggers by transformer T1. C1 discharges through the
emitter of Q1. While the TRIAC is conducting, the voltage
drop between points A and B falls below the breakdown
voltage of D5. Therefore, during the conduction period, the
voltage on C1 is determined by the voltage drop from A to
B and by resistors R1, R2, and R3. Since the voltage
between A and B is a function of motor current due to
resistor R5, C1 is charged during the conduction period to a
value which is proportional to the motor current. The value
of R5 is chosen so that C1 cannot charge to a high enough
voltage to fire Q1 during the conduction period. However,
the amount of charging required to fire Q1 has been
decreased by an amount proportional to the motor current.
Therefore, the firing angle at which Q1 will fire has been
advanced in proportion to the motor current. As the motor
is loaded and draws more current, the firing angle of Q1 is
advanced even more, causing a proportionate increase in
the rms voltage applied to the motor, and a consequent
increase in its available torque.
Since the firing voltage of Q1 depends on the voltage
from base one to base two, it is necessary to support the
base two voltage during the conduction portion of the cycle
to prevent the feedback voltage from firing Q1. D6 and C2
perform this function.
Because the motor is an inductive load, it is necessary to
limit the commutation dv/dt for reliable circuit operation.
R6 and C3 perform this function.
AC LINE VOLTAGE
D1
R3
R1
R4
R2
D2
C1
MOT
Figure 6.11. Circuit Diagram for Controlling
Permanent-Magnet Motors
A small amount of cycle skipping can be experienced at
low speeds using this control, but not enough to necessitate
further development work. Since the voltage generated
during off time is very high, the thermal runaway problem
does not appear at all. Typical speed-torque curves for
motors of this type are shown in Figure 6.12.
VR
VR = FULL RATED VOLTAGE
SPEED
3/4 VR
1/2 VR
1/4 VR
TORQUE
Figure 6.12. Speed-Torque
Characteristic of Permanent-Magnet
Motors at Various Applied Voltages
MOTOR SPEED CONTROL WITH FEEDBACK
While many motor speed control circuits have used
SCRs, the TRIAC has not been very popular in this
application. At first glance, it would appear that the TRIAC
would be perfect for speed control because of its bilateral
characteristics. There are a couple of reasons why this is
not true. The major difficulty is the TRIAC’s dv/dt characteristic. Another reason is the difficulty of obtaining a feedback signal because of the TRIAC’s bilatera nature.
While the TRIAC has its disadvantages, it does offer
some advantages. In a SCR speed control either two SCRs
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A
R1
D1
115 VAC
60 Hz
18 k
2W
R2
27 k
D2
R3
50 k
IN4006(4)
D3
D6
1N4001
Q1
2N6027
D5
ZENER
9.1 V
D4
C1
0.1 μF
R4
16 k
Q2
MAC9D
C2
10 μF
10 V
R6
100 Ω
C3
0.1 μF
R7
27 k
T1
DALE
PT-50 ORIGIN
R5
SEE TABLE
B
NOMINAL R5 VALUES
MOTOR
R5
Motor Rating
(Amperes)
OHMS
Watts
2
1
5
3
0.67
10
6.5
0.32
15
R5 2
IM
IM = Max. Rated
Motor Current
(RMS)
Figure 6.13. Motor Speed Control with Feedback
line half cycle and compared to an external set voltage
determines the firing angle. Negative gate pulses drive the
triac in quadrants two and three.
Because the speed of a universal motor decreases as
torque increases, the TDA1185A lengthens the triac
conduction angle in proportion to the motor current, sensed
through resistor R9.
The TDA1185A is the best solution for low cost
applications tolerating 5% motor speed variation. Open
loop systems do not have a tachometer or negative
feedback and consequently cannot provide perfect speed
compensation.
Nominal values for R5 can be obtained from the table or
they can be calculated from the equation given. Exact
values for R5 depend somewhat on the motor characteristics. Therefore, it is suggested that R5 be an adjustable
wirewound resistor which can be calibrated in terms of
motor current, and the speed control can be adapted to
many different motors. If the value of R5 is too high,
feedback will be excessive and surging or loss of control
will result. If the value is too low, a loss of torque will
result. The maximum motor current flows through R5, and
its wattage must be determined accordingly.
This circuit has been operated successfully with 2 and 3
ampere 1/4-inch drills and has satisfactorily controlled
motor speeds down to 1/3 or less of maximum speed with
good torque characteristics. to the motor, and a consequent
increase in its available torque.
CONSTANT SPEED MOTOR CONTROL USING
TACHOMETER FEEDBACK
Tachometer feedback sensing rotor speed provides
excellent performance with electric motors. The principal
advantages to be gained from tachometer feedback are the
ability to apply feedback control to shaded-pole motors,
and better brush life in universal motors used in feedback
circuits. This latter advantage results from the use of
full-wave rather than half-wave control, reducing the peak
currents for similar power levels.
AN INTEGRATED CIRCUIT FEEDBACK
CONTROL
The TDA1185A TRIAC phase angle controller
(Figure 6.14) generates controlled triac triggering pulses
and applies positive current feedback to stabilize the speed
of universal motors. A ramp voltage synchronized to the ac
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+
100
14
100 μF
C8
8
1.0 μF
120 k
POSITIVE
FEEDBACK
9
FULL-WAVE
TRIGGER PULSE
GENERATOR
2
R9
0.05
FULL-WAVE
R12
+
−
12
SET
MAC8D
820 k
6
MONITORING
+
CURRENT
SYNCHRO
M
RCOMPENSATION
C13
SOFT
START
13
+
10
4
R10
C4
−V CC 1
SAWTOOTH
GENERATOR
7
820 k
VOLTAGE SYNCHRO
2.0 W
PROGRAMMING PIN
18 k
MAIN LINE
VOLTAGE COMPENSATION
1N4005
Figure 6.14. TDA 1185-A Universal Motor Speed Control — Internal Block Diagram/Pin Assignment
THE TACHOMETER
relatively low reluctance; then as the motor turns the
reluctance will increase until one fan blade is precisely
centered between the poles of the magnet. As rotation
continues, the reluctance will then alternately increase and
decrease as the fan blades pass the poles of the magnet. If a
bar- or L-shaped magnet is used so that one pole is close to
the shaft or the frame of the motor and the other is near the
fan blades, the magnetic path reluctance will vary as each
blade passes the magnet pole near the fan. In either case the
varying reluctance causes variations in the circuit flux and
a voltage is generated in the coil wound around the magnet.
The voltage is given by the equation:
The heart of this system is, of course, the speed-sensing
tachometer itself. Economy being one of the principal
goals of the design, it was decided to use a simple magnetic
tachometer incorporating the existing motor fan as an
integral part of the magnetic circuit. The generator consists
of a coil wound on a permanent magnet which is placed so
that the moving fan blades provide a magnetic path of
varying reluctance as they move past the poles of the
magnet. Several possible configurations of the magnetic
system are shown in Figure 6.15.
Flux in a magnetic circuit can be found from the
“magnetic Ohm’s law”:
e –N
φ MMF ,
R
φ = the flux,
MMF = the magnetomotive force (strength of
the magnet), and
R = the reluctance of the magnetic path.
Assuming the MMF of the permanent magnet to be
constant, it is readily apparent that variations in reluctance
will directly affect the flux. The steel fan blades provide a
low-reluctance path for the flux once it crosses the air gap
between them and the poles of the magnet. If the magnet
used has a horseshoe or U shape, and is placed so that
adjacent fan blades are directly opposite each pole in one
position of the motor armature, the magnetic path will be of
where
where
dφ
x 10 –8,
dt
e = the coil voltage in volts,
N = the number of turns in the coil, and
dφ = the rate of change of flux in lines per
second.
dt
In a practical case, a typical small horseshoe magnet wound
with 1000 turns of wire generated a voltage of about
0.5 volts/1000 rpm when mounted in a blender.
Since both generated voltage and frequency are directly
proportional to the motor speed, either parameter can be
used as the feedback signal. However, circuits using
voltage sensing are less complex and therefore less
expensive. Only that system will be discussed here.
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COIL WIRES
MAGNET
FAN
MOTOR
ARMATURE
MOTOR FAN
MOTOR
ARMATURE
SIDE VIEW
MOTOR FAN
COIL
WIRES
FERROUS
MOTOR HOUSING
MOTOR
ARMATURE
MAGNET
POSSIBLE MAGNET SHAPES
AND LOCATIONS
TOP VIEW
Figure 6.15. (a). Locations for Magnetic Sensing
Tachometer Generator Using a Horseshoe Magnet
(b). Locations for Magnetic Sensing Tachometer
Generator Using an “L” or Bar Magnet
THE ELECTRONICS
set so that with no tachometer output the transistor is just
barely in conduction. As the tachometer output increases,
QT is cut off on negative half cycles and conducts on
positive half cycles. Resistors R9 and R10 provide a fixed
gain for this amplifier stage, providing the hFE of QT is
much greater than the ratio of R9 to R10. Thus the output
of the amplifier is a fixed multiple of the positive values of
the tachometer waveform. The rectifier diode D1 prevents
C1 from discharging through R9 on negative half cycles of
the tachometer. The remainder of the filter and control
circuitry is the same as the basic circuit.
In the second variation, shown in 6.16(c), R8 has been
replaced by a semiconductor diode, D2. Since the voltage
and temperature characteristics more closely match those
of the transistor base-to-emitter junction, this circuit is
easier to design and needs no initial adjustments as does the
circuit in 6.16(b). The remainder of this circuit is identical
to that of Figure 6.15.
In the second basic circuit, which is shown in Figure 6.17,
the rectified and filtered tachometer voltage is added to the
output voltage of the voltage divider formed by R1 and R2.
If the sum of the two voltages is less than V1 − VBE Q1
(where VBE Q1 is the base-emitter voltage of Q1), Q1 will
conduct a current proportional to V1 − VBE Q1, charging
capacitor C. If the sum of the two voltages is greater than V1
− VBE Q1, Q1 will be cut off and no current will flow into the
capacitor. The operation of the remainder of the circuit is the
same as the previously described circuits.
In one basic circuit, which is shown in Figure 6.16, the
generator output is rectified by rectifier D1, then filtered
and applied between the positive supply voltage and the
base of the detector transistor Q1. This provides a negative
voltage which reduces the base-voltage on Q1 when the
speed increases.
The emitter of the detector transistor is connected to a
voltage divider which is adjusted to the desired tachometer
output voltage. In normal operation, if the tachometer
voltage is less than desired, the detector transistor, Q1, is
turned on by current through R1 into its base. Q1 then turns
on Q2 which causes the timing capacitor for programmable
unijunction transistor Q3 to charge quickly.
As the tachometer output approaches the voltage desired,
the base-emitter voltage of Q1 is reduced to the point at
which Q1 is almost cut off. Thereby, the collector current
of Q2, which charges the PUT timing capacitor, reduces,
causing it to charge slowly and trigger the thyristor later in
the half cycle. In this manner, the average power to the
motor is reduced until just enough power to maintain the
desired motor speed is allowed to flow.
Input circuit variations are used when the tachometer
output voltage is too low to give a usable signal with a
silicon rectifier. In the variation shown in Figure 6.16(b),
the tachometer is connected between a voltage divider and
the base of the amplifier transistor. The voltage divider is
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101
C1
+V
1
R1
(PURE dc)
R2
R3
R5
Q2
D1
Q1
(PULSING dc)
+V2
R6
TACHOMETER
GENERATOR
PHASE CONTROL WITH PROGRAMMABLE
UNIJUNCTION TRANSISTORS
LOAD
120 V
AC
R4
INPUT CIRCUIT
control circuit, the thyristor switches on for the remainder
of the half cycle. By controlling the phase angle at which
the thyristor is switched on, the relative power in the load
may be controlled.
PUTs provide a simple, convenient means for obtaining
the thyristor trigger pulse synchronized to the ac line at a
controlled phase angle.
C2
DETECTOR AND POWER
CONTROL CIRCUIT
Figure 6.16. (a). Basic Tachometer Control Circuit
+V1 (PURE dc)
+V2 PULSATING dc
R1
TACH
R9
R7
C1
Q1
R1
120 VAC
TACH
QT
R8
LOAD
R2
D1
C
R10
Figure 6.17. Another Basic Tachometer Circuit
(b). Variation Used when the Tachometer Output is
Too Low for Adequate Control
R9
C1
R7
These circuits are all based on the simple relaxation
oscillator circuit of Figure 6.18. RT and CT in the figure
form the timing network which determines the time
between the application of voltage to the circuit (represented by the closing of S1) and the initiation of the pulse.
In the case of the circuit shown, with Vs pure dc, the
oscillator is free running, RT and CT determine the
frequency of oscillation. The peak of the output pulse
voltage is clipped by the forward conduction voltage of the
gate to cathode diode in the thyristor. The principal
waveforms associated with the circuit are shown in
Figure 6.18(b).
Operation of the circuit may best be described by
referring to the capacitor voltage waveform. Following
power application, CT charges at the rate determined by its
own capacitance and the value of RT until its voltage
reaches the peak point voltage of the PUT. Then the PUT
switches into conduction, discharging CT through RGK and
the gate of the thyristor. With Vs pure dc, the cycle then
repeats immediately; however, in many cases Vs is derived
from the anode voltage of the thyristor so that the timing
cycle cannot start again until the thyristor is blocking
forward voltage and once again provides Vs.
R1
TACH
QT
D2
D1
R10
(c). Variation Providing Better Temperature Tracking
and Easier Initial Adjustment
PHASE CONTROL WITH TRIGGER DEVICES
Phase control using thyristors is one of the most common
means of controlling the flow of power to electric motors,
lamps, and heaters. With an ac voltage applied to the
circuit, the gated thyristor (SCR, TRIAC, etc.) remains in
its off-state for the first portion of each half cycle of the
power line, then, at a time (phase angle) determined by the
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RT
RB1
In this circuit, RD is selected to limit the current through D1
so that the diode dissipation capability is not exceeded.
Dividing the allowable diode dissipation by one-half the
zener voltage will give the allowable positive current in the
diode since it is conducting in the voltage regulating mode
only during positive half cycles. Once the positive halfcycle current is found, the resistor value may be calculated
by subtracting 0.7 times the zener voltage from the rms line
voltage and dividing the result by the positive current:
LOAD
A
G
CT
VS
RB2
K
RGK
(a)
RD E rms 0.7 V z
I positive
The power rating of RD must be calculated on the basis of
full wave conduction as D1 is conducting on the negative
half cycle acting as a shunt rectifier as well as providing Vs
on the positive half cycle.
V CT
CAPACITOR
VOLTAGE
Von
Voff
RD
RT
R1
V
V RB1
OUTPUT VOLTAGE
D1
VS
CT
VCG
R2
R3
IBBRB1
LINE
0
(a)
(b)
RECTIFIED
SINE WAVE
VS
Figure 6.18. Basic Relaxation Oscillator Circuit (a)
and Waveforms (b)
It is often necessary to synchronize the timing of the
output pulses to the power line voltage zero-crossing
points. One simple method of accomplishing synchronization is shown in Figure 6.19. Zener diode D1 clips the
rectified supply voltage resulting in a Vs as shown in
6.19(b). Since VS, and therefore the peak point voltage of
the PUT drops to zero each time the line voltage crosses
zero, CT discharges at the end of every half cycle and
begins each half cycle in the discharged state. Thus, even if
the PUT has not triggered during one half cycle, the
capacitor begins the next half cycle discharged. Consequently, the values of RT and CT directly control the phase
angle at which the pulse occurs on each half cycle. The
zener diode also provides voltage stabilization for the
timing circuit giving the same pulse phase angle regardless
of normal line voltage fluctuations.
(b)
Figure 6.19. Control Circuit (a) with Zener
Clipped, Rectified Voltage (b)
LOAD
600 W
AC
LINE
APPLICATIONS
RD
6.8 k
2W
RT
D1
1N5250
A
CT
0.1 μF
100 k
2N6027
R3
R1
5.1 k
R2
10 k
MCR8D
100 k
Figure 6.20. Half Wave Control Circuit with Typical
Values for a 600 Watt Resistive Load
The most elementary application of the PUT trigger
circuit, shown in Figure 6.20, is a half-wave control circuit.
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103
The thyristor is acting both as a power control device and
a rectifier, providing variable power to the load during the
positive half cycle and no power to the load during the
negative half cycle. The circuit is designed to be a two
terminal control which can be inserted in place of a switch.
If full wave power is desired as the upper extreme of this
control, a switch can be added which will short circuit the
SCR when RT is turned to its maximum power position.
The switch may be placed in parallel with the SCR if the
load is resistive; however, if the load is inductive, the load
must be transferred from the SCR to the direct line as
shown in Figure 6.21.
Full wave control may be realized by the addition of a
bridge rectifier, a pulse transformer, and by changing the
thyristor from an SCR to a TRIAC, shown in Figure 6.22.
Occasionally a circuit is required which will provide
constant output voltage regardless of line voltage changes.
Adding potentiometer P1, as shown in Figure 6.23, to the
circuits of Figures 6.20 and 6.22, will provide an approximate solution to this problem. The potentiometer is
adjusted to provide reasonably constant output over the
desired range of line voltage. As the line voltage increases,
so does the voltage on the wiper of P1 increasing VS and
thus the peak point voltage of the PUT. The increased peak
point voltage results in CT charging to a higher voltage and
thus taking more time to trigger. The additional delay
reduces the thyristor conduction angle and maintains the
average voltage at a reasonably constant value.
CONTROL
CIRCUIT
FEEDBACK CIRCUITS
The circuits described so far have been manual control
circuits; i.e., the power output is controlled by a
potentiometer turned by hand. Simple feedback circuits
may be constructed by replacing RT with heat or
light-dependent sensing resistors; however, these circuits
have no means of adjusting the operating levels. The
addition of a transistor to the circuits of Figures 6.20 and
6.22 allows complete control.
(a). Resistive Load
CONTROL
CIRCUIT
RD
6.8 k
RECTIFIED
LINE
(FULL OR
HALF WAVE)
(b). Inductive Load
Figure 6.21. Half Wave Controls with Switching for
Full Wave Operation
P1
500
RT
D1
1N5250A
CT
0.1 μF
5.1 k
RG1
100 k
2N6027
RG2
10 k
100
TO THYRISTOR
RGK
GATE-CATHODE
Figure 6.23. Circuit for Line Voltage
Compensation
LOAD
900 W
LINE
MDA920A4
RD
6.8 k
2W
1N5250
A
RT
R1
100 k
2N6027
6.8 k
5.1 k
RD
10 k
RECTIFIED
LINE
(FULL OR
HALF WAVE)
R2
D1
CT
0.1 μF
RT(MIN)
Rs*
MAC12D
R3
100 k
1N5250A
D1
Rc
100 k
DALE
PT50
(OR EQUIVALENT)
Q1
5.1 k
10 k
MPS6512
2N6027
CT
0.1 μF
10 k
100
*Rs SHOULD BE SELECTED TO BE ABOUT
3 k TO 5 k OHMS AT THE DESIRED OUTPUT LEVEL
Figure 6.22. A Simple Full Wave Trigger Circuit with
Typical Values for a 900 Watt Resistive Load
TO THYRISTOR
GATE-CATHODE
Figure 6.24. Feedback Control Circuit
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104
gain. To solve this problem a dc amplifier could be inserted
between the voltage divider and the control transistor gate
to provide as close a control as desired. Other modifications to add multiple inputs, switched gains, ramp and
pedestal control, etc., are all simple additions to add
sophistication.
Figure 6.24 shows a feedback control using a sensing
resistor for feedback. The sensing resistor may respond to
any one of many stimuli such as heat, light, moisture,
pressure, or magnetic field. Rs is the sensing resistor and Rc
is the control resistor that establishes the desired operating
point. Transistor Q1 is connected as an emitter follower
such that an increase in the resistance of Rs decreases the
voltage on the base of Q1, causing more current to flow.
Current through Q1 charges CT, triggering the PUT at a
delayed phase angle. As Rs becomes larger, more charging
current flows, causing the capacitor voltage to increase
more rapidly. This triggers the PUT with less phase delay,
boosting power to the load. When Rs decreases, less power
is applied to the load. Thus, this circuit is for a sensing
resistor which decreases in response to too much power in
the load. If the sensing resistor increases with load power,
then Rs and Rc should be interchanged.
If the quantity to be sensed can be fed back to the circuit
in the form of an isolated, varying dc voltage such as the
output of a tachometer, it may be inserted between the
voltage divider and the base of Q1 with the proper polarity.
In this case, the voltage divider would be a potentiometer to
adjust the operating point. Such a circuit is shown in
Figure 6.25.
MCR218-4
RD
1N5250A
Rc
100 k
2N6027
es
MPS6512
R1
0.1 μF
10 k
CT
1N5250A
3.9 k
2k
T
DALE PT50
(OR EQUIVALENT)
Q1
MPS6512
2N6028
C1
10 μF
CT
0.1 μF
T
R1
100 k
DC
LOAD
600 W
R2
30 k
Figure 6.26. Half Wave, Average Voltage Feedback
RG
10
T
RG
10
MCR218-4
(2)
R1
100 k
MPS6512
2k
Q1
6.8 k
RD 2 W
R2
30 k
2N6028
5.1 k TO
THYRISTOR
GATECATHODE
1N4003
(2)
100
1N4721
(2)
D1
1N5250A
3.9 k
RECTIFIED
LINE
RT(MIN)
RC
1k
AC
LINE
6.8 k
10 k
6.8 k
T
CT
0.1 μF
C1
DC
10
LOAD
μF
DALE PT50
(OR EQUIVALENT)
AC LINE
Figure 6.25. Voltage Feedback Circuit
Figure 6.27. Full Wave, Average Voltage
Feedback Control
In some cases, average load voltage is the desired
feedback variable. In a half wave circuit this type of
feedback usually requires the addition of a pulse transformer, shown in Figure 6.26. The RC network, R1, R2, C1,
averages load voltage so that it may be compared with the
set point on Rs by Q1. Full wave operation of this type of
circuit requires dc in the load as well as the control circuit.
Figure 6.27 is one method of obtaining this full wave
control.
Each SCR conducts on alternate half-cycles and supplies
pulsating dc to the load. The resistors (Rg) insure sharing
of the gate current between the simultaneously driven
SCRs. Each SCR is gated while blocking the line voltage
every other half cycle. This momentarily increases reverse
blocking leakage and power dissipation. However, the
leakage power loss is negligible due to the low line voltage
and duty cycle of the gate pulse.
There are, of course, many more sophisticated circuits
which can be derived from the basic circuits discussed
here. If, for example, very close temperature control is
desired, the circuit of Figure 6.24 might not have sufficient
CLOSED LOOP UNIVERSAL MOTOR SPEED
CONTROL
Figure 6.28 illustrates a typical tachometer stabilized
closed feedback loop control using the TDA1285A integrated circuit. This circuit operates off the ac line and
generates a phase angle varied trigger pulse to control the
triac. It uses inductive or hall effect speed sensors, controls
motor starting acceleration and current, and provides a 1 to
2% speed variation for temperature and load variations.
CYCLE CONTROL WITH OPTICALLY
ISOLATED TRIAC DRIVERS
In addition to the phase control circuits, TRIAC drivers
can also be used for ac power control by on-off or burst
control, of a number of ac cycles. This form of power
control allows logic circuits and microprocessors to easily
control ac power with TRIAC drivers of both the zerocrossing and non zero-crossing varieties.
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47 μF
+ 10 k
R1
VCC
C14
47 nF
10
14
1N4005
220 V
820 k
9
Inductive
TACHO
M
820 k
2
1
330 nF
TDA1285A
16
220 k
4
5
8
11
7
13
6 12 3
10 NF
1.0 MΩ
R4
C4
100 nF
0.1 μF
C11
C5
0.1 μF
22 k
220 nF
1.5 μF
2.2 k
C7
220 nF
1.0 μF
R3
Figure 6.28. (a). Motor Control Circuit
TDA1285A
NOTES:
Frequency to Voltage converter
—Max. motor speed 30,000 rpm
6
—Tachogenerator 4 pairs of poles: max. frequency =
12
30, 000
x 4 2 kHz
60
47 k
—C11 = 680 pF. R4 adjusted to obtain VPin 4 = 12 V at max. speed: 68 kΩ
—Power Supply
with Vmains = 120 Vac, R1 = 4.7 kΩ. Perfect operation
will occur down to 80 Vac.
USING NON-ZERO CROSSING OPTICALLY
ISOLATED TRIAC DRIVERS
HALLEFFECT
SENSOR
M
(b). Circuit Modifications
to Connect a Hall-Effect Sensor
switch wiring to be enclosed in conduit. By using a
MOC3011, a TRIAC, and a low voltage source, it is
possible to control a large lighting load from a long
distance through low voltage signal wiring which is
completely isolated from the ac line. Such wiring usually is
not required to be put in conduit, so the cost savings in
installing a lighting system in commercial or residential
buildings can be considerable. An example is shown in
Figure 6.29. Naturally, the load could also be a motor, fan,
pool pump, etc.
USING THE MOC3011 ON 240 VAC LINES
The rated voltage of a MOC3011 is not sufficiently high
for it to be used directly on 240 V line; however, the
designer may stack two of them in series. When used this
way, two resistors are required to equalize the voltage
dropped across them as shown in Figure 6.29.
REMOTE CONTROL OF AC VOLTAGE
Local building codes frequently require all 115 V light
+5V
180
150
LOAD
MOC3011
l
1M
l
1M
240 Vac
MOC3011
1k
Figure 6.29. Two MOC3011 TRIAC Drivers in Series to Drive 240 V TRIAC
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NON-CONDUIT #22 WIRE
180
115 V
360
λ
2N6342A
MOC3011
5V
Figure 6.30. Remote Control of AC Loads Through Low Voltage Non-Conduit Cable
SOLID STATE RELAY
the second input of a 2 input gate is tied to a simple timing
circuit, it will also provide energization of the TRIAC only
at the zero crossing of the ac line voltage as shown in
Figure 6.32. This technique extends the life of incandescent lamps, reduces the surge current strains on the TRIAC,
and reduces EMI generated by load switching. Of course,
zero crossing can be generated within the microcomputer
itself, but this requires considerable software overhead and
usually just as much hardware to generate the zero-crossing
timing signals.
Figure 6.30 shows a complete general purpose, solid
state relay snubbed for inductive loads with input protection. When the designer has more control of the input and
output conditions, he can eliminate those components
which are not needed for his particular application to make
the circuit more cost effective.
INTERFACING MICROPROCESSORS TO 115 VAC
PERIPHERALS
The output of a typical microcomputer input-output
(I/O) port is a TTL-compatible terminal capable of driving
one or two TTL loads. This is not quite enough to drive the
MOC3011, nor can it be connected directly to an SCR or
TRIAC, because computer common is not normally
referenced to one side of the ac supply. Standard 7400
series gates can provide an input compatible with the
output of an MC6821, MC6846 or similar peripheral
interface adaptor and can directly drive the MOC3011. If
APPLICATIONS USING THE ZERO CROSSING
TRIAC DRIVER
For applications where EMI induced, non-zero crossingload switching is a problem, the zero crossing TRIAC
driver is the answer. This TRIAC driver can greatly
simplify the suppression of EMI for only a nominal
increased cost. Examples of several applications using the
MOC3031, 41 follows.
150
180
0.1 μF
λ
2W
1N4002
2.4 k
2N6071B
115 V
MOC3011
2N3904
47
10 k
Figure 6.31. Solid-State Relay
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200 W
+5 V
+5 V
180
7400
ADDRESS
MC6800
OR
MC6802
MPU
DATA
300
MC6820
OR
MC6821
OR
MC6846
I/O
115 V
(RESISTIVE
LOAD)
MOC3011
2N6071
300
180
MOC3011
2.4 k
MOTOR
115 V
(INDUCTIVE
LOAD)
0.1 μF
2N6071B
OPTO TRIAC
DRIVERS
1k
5V
6.3 V
115 V
3k
OPTIONAL
ZERO-CROSSING
CIRCUITRY
2N3904
100 k
Figure 6.32. Interfacing an M6800 Microcomputer System to 115 Vac Loads
MATRIX SWITCHING
to a TRIAC on a horizontal line being switched on. Since
non-zero crossing TRIAC drivers have lower static dv/dt
ratings, this ramp would be sufficiently large to trigger the
device on.
R is determined as before:
Matrix, or point-to-point switching, represents a method
of controlling many loads using a minimum number of
components. On the 115 V line, the MOC3031 is ideal for
this application; refer to Figure 6.33. The large static dv/dt
rating of the MOC3031 prevents unwanted loads from
being triggered on. This might occur, in the case of
non-zero crossing TRIAC drivers, when a TRIAC driver
on a vertical line was subjected to a large voltage ramp due
R (min) V in(pk)
I TSM
170 V 150 ohms
1.2 A
150 Ω
LOAD
LOAD
LOAD
MOC
3031
150 Ω
LOAD
LOAD
LOAD
MOC
3031
150 Ω
LOAD
LOAD
LOAD
MOC
3031
MOC
3031
MOC
3031
MOC
3031
115 V
150 Ω
150 Ω
150 Ω
CONTROL BUS
Figure 6.33. Matrix Switching
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108
300 Ω
MOC
3041
LOAD
LOAD
LOAD
230 VAC
POWER
RELAY
(230 VAC COIL)
LOAD
CONTROL
Figure 6.34. Power Relay Control
POWER RELAYS
the I/O port and in turn, drive the MOC3031 and/or
MOC3041; refer to Figure 6.35.
The zero-crossing feature of these devices extends the
life of incandescent lamps, reduces inrush currents and
minimizes EMI generated by load switching.
The use of high-power relays to control the application
of ac power to various loads is a very widespread practice.
Their low contact resistance causes very little power loss
and many options in power control are possible due to their
multipole-multithrow capability. The MOC3041 is well
suited to the use of power relays on the 230 Vac line; refer
to Figure 6.34. The large static dv/dt of this device makes a
snubber network unnecessary, thus reducing component
count and the amount of printed circuit board space
required. A non-zero crossing TRAIC driver (MOC3021)
could be used in this application, but its lower static dv/dt
rating would necessitate a snubber network.
AC MOTORS
The large static dv/dt rating of the zero-crossing TRIAC
drivers make them ideal when controlling ac motors.
Figure 6.36 shows a circuit for reversing a two phase motor
using the MOC3041. The higher voltage MOC3041 is
required, even on the 115 Vac line, due to the mutual and
self-inductance of each of the motor windings, which may
cause a voltage much higher than 115 Vac to appear across
the winding which is not conducting current.
MICROCOMPUTER INTERFACE
DETERMINING LIMITING RESISTOR R FOR A
HIGH-WATTAGE INCANDESCENT LAMP
The output of most microcomputer input/output (I/O)
ports is a TTL signal capable of driving several TTL gates.
This is insufficient to drive a zero-crossing TRIAC driver.
In addition, it cannot be used to drive an SCR or TRIAC
directly, because computer common is not usually referenced to one side of the ac supply. However, standard 7400
NAND gates can be used as buffers to accept the output of
Many high-wattage incandescent lamps suffer shortened
lifetimes when switched on at ac line voltages other than
zero. This is due to a large inrush current destroying the
filament. A simple solution to this problem is the use of the
MOC3041 as shown in Figure 6.37. The MOC3041 may be
controlled from a switch or some form of digital logic.
+5 V
200 W
+5 V
ADDRESS
MC68000
MPU
DATA
150 Ω
300
7400
MOC
3031
MC6820
OR
MC6821
OR
MC6846
I/O
2N6071
300 Ω
300
MOC
3041
1 kΩ
+5 V
Figure 6.35. M68000 Microcomputer Interface
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115 V
(RESISTIVE
LOAD)
MOTOR
2N6073
230 V
(INDUCTIVE
LOAD)
MOTOR
OPTIONAL
CURRENT LIMITING RESISTOR
115 V
R
C
300
300
MOC
3041
MOC
3041
Figure 6.36. Reversing Motor Circuit
e. Zero Voltage Switching Output
(Will Only Turn On Close to Zero Volts)
f. AC Output (50 or 60 Hz)
The minimum value of R is determined by the maximum
surge current rating of the MOC3041 (ITSM):
R (min) V in(pk)
I TSM
Figure 6.38 shows the general format and waveforms of
the SSR. The input on/off signal is conditioned (perhaps
only by a resistor) and fed to the Light-Emitting-Diode
(LED) of an optoelectronic-coupler. This is ANDed with a
go signal that is generated close to the zero-crossing of the
line, typically 10 Volts. Thus, the output is not gated on
via the amplifier except at the zero-crossing of the line
voltage. The SSR output is then re-gated on at the
beginning of every half-cycle until the input on signal is
removed. When this happens, the thyristor output stays on
until the load current reaches zero, and then turns off.
(10)
V in(pk)
1.2 A
On a 230 Vac Line:
R (min) 340 V 283 ohms
1.2 A
(11)
In reality, this would be a 300 ohm resistor.
AC POWER CONTROL WITH SOLID-STATE
RELAYS
The Solid-State Relay (SSR) as described below, is a
relay function with:
a. Four Terminals (Two Input, Two Output)
b. DC or AC Input
c. Optical Isolation Between Input and Output
d. Thyristor (SCR or TRIAC) Output
ADVANTAGES AND DISADVANTAGES OF SSRs
The SSR has several advantages that make it an
attractive choice over its progenitor, the Electromechanical
Relay (EMR) although the SSR generally costs more than
its electromechanical counterpart. These advantages are:
LAMP
R
SWITCH OR
DIGITAL LOGIC
MOC
3041
300
Figure 6.37. High-Wattage Lamp Control
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110
230 V
ZERO CROSS
DETECTOR
LOAD
GO/NO GO
INPUT
ON/OFF
LED
POWER
SWITCH
AND
AMPL
LINE
This list of advantages is impressive, but of course, the
designer has to consider the following disadvantages:
1. Voltage Transient Resistance — the ac line is not
the clean sine wave obtainable from a signal generator.
Superimposed on the line are voltage spikes from
motors, solenoids, EMRs (ironical), lightning, etc. The
solid-state components in the SSR have a finite voltage
rating and must be protected from such spikes, either
with RC networks (snubbing), zener diodes, MOVs or
selenium voltage clippers. If not done, the thyristors
will turn on for part of a half cycle, and at worst, they
will be permanently damaged, and fail to block voltage. For critical applications a safety margin on voltage
of 2 to 1 or better should be sought.
The voltage transient has at least two facets — the first
is the sheer amplitude, already discussed. The second is
its frequency, or rate-of-rise of voltage (dv/dt). All thyristors are sensitive to dv/dt to some extent, and the transient
must be snubbed, or “soaked up,” to below this level with
an RC network.(1) Typically this rating (“critical” or
“static” dv/dt) is 50 to 100 V/μs at maximum temperature. Again the failure mode is to let through, to a halfcycle of the line, though a high energy transient can cause
permanent damage. Table 6.1 gives some starting points
for snubbing circuit values. The component values
required depend on the characteristics of the transient,
which are usually difficult to quantify. Snubbing across
the line as well as across the SSR will also help.
LINE 0
GO
NO GO
ON
OFF
OUTPUT
Figure 6.38. SSR Block Diagram
1. No Moving Parts — the SSR is all solid-state. There
are no bearing surfaces to wear, springs to fatigue,
assemblies to pick up dust and rust. This leads to several other advantages.
2. No Contact Bounce — this in turn means no contact
wear, arcing, or Electromagnetic Interference (EMI)
associated with contact bounce.
3. Fast Operation — usually less than 10 μs. Fast turn-on
time allows the SSR to be easily synchronized with
line zero-crossing. This also minimizes EMI and can
greatly increase the lifetime of tungsten lamps, of considerable value in applications such as traffic signals.
4. Shock and Vibration Resistance — the solid-state contact cannot be “shaken open” as easily as the EMR
contact.
5. Absence of Audible Noise — this devolves from the
lack of moving mechanical parts.
6. Output Contact Latching — the thyristor is a latching
device, and turns off only at the load current zerocrossing, minimizing EMI.
7. High Sensitivity — the SSR can readily be designed to
interface directly with TTL and CMOS logic, simplifying circuit design.
8. Very Low Coupling Capacitance Between Input and
Output. This is a characteristic inherent in the optoelectronic-coupler used in the SSR, and can be useful in
areas such as medical electronics where the reduction
of stray leakage paths is important.
Table 6.1. Typical Snubbing Values
Load Current
A rms
Resistance
Ω
Capacitance
μF
5
47
0.047
10
33
0.1
25
10
0.22
40
22
0.47
1. For a more thorough discussion of snubbers, see page 38.
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111
+
+
INPUT
LOAD
R11
R1
C1
R2
R4
R6
SCR1
R13
OC1
Q1
BR
11
Q2
TR11
D2
C11
R7
D1
C2
R12
R5
R3
−
−
INPUT AND CONTROL CIRCUIT
TRIAC POWER CIRCUIT
LINE
Figure 6.39 (a). TRIAC SSR Circuit
CONTROL CIRCUIT OPERATION
2. Voltage Drop — The SSR output contact has some
offset voltage — approximately 1 V, depending on current, causing dissipation. As the thyristor has an operating temperature limit of +125°C, this heat must be
removed, usually by conduction to air via a heat sink or
the chassis.
3. Leakage Current — When an EMR is open, no current
can flow. When an SSR is open however, it does not
have as definite an off condition. There is always some
current leakage through the output power switching
thyristor, the control circuitry, and the snubbing network. The total of this leakage is usually 1 to 10 mA
rms — three or four orders of magnitude less than the
on-state current rating.
4. Multiple Poles — are costly to obtain in SSRs, and
three phase applications may be difficult to implement.
5. Nuclear Radiation — SSRs will be damaged by
nuclear radiation.
The operation of the control circuit is straightforward.
The AND function of Figure 6.38 is performed by the
wired-NOR collector configuration of the small-signal
transistors Q1 and Q2. Q1 clamps the gate of SCR1 if
optoelectronic-coupler OC1 is off. Q2 clamps the gate if
there is sufficient voltage at the junction of the potential
divider R4,R5 to overcome the VBE of Q2. By judicious
selection of R4 and R5, Q2 will clamp SCR1’s gate if more
than approximately 5 Volts appear at the anode of SCR1;
i.e., Q2 is the zero-crossing detector.
Table 6.2. Control Circuit Parts List
Line Voltage
TRIAC SSR CIRCUIT
Many SSR circuits use a TRIAC as the output switching
device. Figure 6.39(a) shows a typical TRIAC SSR circuit.
The control circuit is used in the SCR relay as well, and is
defined separately. The input circuit is TTL compatible.
Output snubbing for inductive loads will be described later.
A sensitive-gate SCR (SCR1) is used to gate the power
TRIAC, and a transistor amplifier is used as an interface
between the optoelectronic-coupler and SCR1. (A sensitive-gate SCR and a diode bridge are used in preference to
a sensitive gate TRIAC because of the higher sensitivity of
the SCR.)
Part
120 V rms
240 V rms
C1
C2
D1
D2
OC1
Q1
Q2
R1
R2
R3
R4
R5
R6
R7
SCR1
220 pF, 20%, 200 Vdc
0.022 μF, 20%, 50 Vdc
1N4001
1N4001
MOC1005
MPS5172
MPS5172
1 kΩ, 10%, 1 W
47 kΩ, 5%, 1/2 W
1 MΩ, 10%, 1/4 W
110 kΩ, 5%, 1/2 W
15 kΩ, 5%, 1/4 W
33 kΩ, 10%, 1/2 W
10 kΩ, 10%, 1/4 W
2N5064
100 pF, 20%, 400 Vdc
0.022 μF, 20%, 50 Vdc
1N4001
1N4001
MOC1005
MPS5172
MPS5172
1 kΩ, 10%, 1 W
100 kΩ, 5%, 1 W
1 MΩ, 10%, 1/4 W
220 kΩ, 5%, 1/2 W
15 kΩ, 5%, 1/4 W
68 kΩ, 10%, 1 W
10 kΩ, 10%, 1/4 W
2N6240
If OC1 is on, Q1 is clamped off, and SCR1 can be turned
on by current flowing down R6, only if Q2 is also off —
which it is only at zero crossing.
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CROSSING
LINE ZERO
VSCR1
(b)
ZERO" VOLTAGE
FIRING LEVEL
E
(c)
FIRING
WINDOW
WITHOUT
C1 AND C2
FIRING
WINDOW
(d)
FIRING
WINDOW
WITH
C1 AND C2
FIRING WINDOW
Figure 6.39. Firing Windows
The capacitors are added to eliminate circuit race
conditions and spurious firing, time ambiguities in
operation. Figure 6.39(b) shows the full-wave rectified
line that appears across the control circuit. The zero
voltage firing level is shown in 6.39(b) and 6.39(c),
expanded in time and voltage. A race condition exists
on the up-slope of the second half-cycle in that SCR1
may be triggered via R6 before Q1 has enough base
current via R2 to clamp SCR1’s gate. C1 provides
current by virtue of the rate of change of the supply
voltage, and Q1 is turned on firmly as the supply voltage
starts to rise, eliminating any possibility of unwanted
firing of the SSR; thus eliminating the race condition.
This leaves the possibility of unwanted firing of the
SSR on the down-slope of the first half cycle shown. C2
provides a phase shift to the zero voltage potential
divider, and Q2 is held on through the real zero-crossing. The resultant window is shown in 6.39(d).
CONTROL CIRCUIT COMPONENTS
The parts list for the control circuit at two line
voltages is shown in Table 6.2.
R1 limits the current in the input LED of OC1. The
input circuit will function over the range of 3 to 33 Vdc.
D1 provides reverse voltage protection for the input
of OC1.
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are in the half-inch pressfit package in the isolated stud
configuration; the plastic TRIACs are in the TO-220
Thermowatt package. R12 is chosen by calculating the
peak control circuit off-state leakage current and ensuring
that the voltage drop across R12 is less than the VGT(MIN)
of the TRIAC.
C11 must be an ac rated capacitor, and with R13 provides
some snubbing for the TRIAC. The values shown for this
network are intended more for inductive load commutating
dv/dt snubbing than for voltage transient suppression.
Consult the individual data sheets for the dissipation,
temperature, and surge current limits of the TRIACs.
D2 allows the gate of SCR1 to be reverse biased,
providing better noise immunity and dv/dt performance.
R7 eliminates pickup on SCR1’s gate through the
zero-crossing interval.
SCR1 is a sensitive gate SCR; the 2N5064 is a TO-92
device, the 2N6240 is a Case 77 device.
Alternatives to the simple series resistor (R1) input
circuit will be described later.
POWER CIRCUIT COMPONENTS
The parts list for the TRIAC power circuit in
Figure 6.39(a) is shown in Table 6.3 for several rms
current ratings, and two line voltages. The metal TRIACs
Table 6.3. TRIAC Power Circuit Parts List
Voltage
120 V rms
240 V rms
rms Current Amperes
8
12
25
40
8
12
25
40
BR11
IN4004(4)
IN4004(4)
IN4004(4)
IN4004(4)
IN4004(4)
IN4004(4)
IN4004(4)
IN4004(4)
0.047
0.047
0.1
0.1
0.047
0.047
0.1
0.1
R11
(10%, 1 W)
39
39
39
39
39
39
39
39
R12
(10%, 1/2 W)
18
18
18
18
18
18
18
18
R13
(10%, 1/2 W)
620
620
330
330
620
620
330
330
2N6344
2N6344A
—
—
2N6344
2N6344A
—
—
C11, μF
(10%, line voltage ac
rated)
TR11
Plastic
TRIACs AND INDUCTIVE LOADS
The TRIAC is a single device which to some extent is the
equivalent of two SCRs inverse parallel connected; certainly this is so for resistive loads. Inductive loads however,
can cause problems for TRIACs, especially at turn-off.
A TRIAC turns off every line half-cycle when the line
current goes through zero. With a resistive load, this
coincides with the line voltage also going through zero.
The TRIAC must regain blocking-state before there are
more than 1 or 2 Volts of the reverse polarity across it — at
120 V rms, 60 Hz line this is approximately 30 μs. The
TRIAC has not completely regained its off-state characteristics, but does so as the line voltage increases at the 60 Hz
rate.
Figure 6.40 indicates what happens with an inductive or
lagging load. The on signal is removed asynchronously and
the TRIAC, a latching device, stays on until the next
current zero. As the current is lagging the applied voltage,
the line voltage at that instant appears across the TRIAC. It
is this rate-of-rise of voltage, the commutating dv/dt, that
must be limited in TRIAC circuits, usually to a few volts
per microsecond. This is normally done by use of a snubber
network RS and CS as shown in Figure 6.41.
SCRs have less trouble as each device has a full
half-cycle to turn off and, once off, can resist dv/dt to the
critical value of 50 to 100 V/μs.
CHOOSING THE SNUBBING COMPONENTS(1)
There are no easy methods for selecting the values of RS
and CS in Figure 6.41 required to limit commutating dv/dt.
The circuit is a damped tuned circuit comprised by RS, CS,
RL and LL, and to a minor extent the junction capacitance
of the TRIAC. At turn-off this circuit receives a step
impulse of line voltage which depends on the power factor
of the load. Assuming the load is fixed, which is normally
the case, the designer can vary RS and CS. CS can be
increased to decrease the commutating dv/dt; RS can be
increased to decrease the resonant over-ring of the tuned
circuit — to increase damping. This can be done empirically, beginning with the values for C11 and R13 given in
Table 6.3, and aiming at close to critical damping and the
data sheet value for commutating dv/dt. Reduced temperatures, voltages, and off-going di/dt (rate-of-change of
current at turn-off) will give some safety margin.
1. For a more thorough discussion of snubbers, see page 38.
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ON
ON/OFF
SIGNAL
OFF
LOAD CURRENT
0
(LAGGING LOAD)
LINE VOLTAGE
dv/dt
0
LINE AND
TRIAC VOLTAGE
TRIAC VOLTAGE
Figure 6.40. Commutating dv/dt
Table 6.4. SCR Power Circuit Parts List
Voltage
120 V rms
rms Current Amperes
5
11
22
C21 (10%, line voltage ac rated)
240 V rms
49
5
11
22
49
SEE TEXT
D21-24
1N4003
1N4003
1N4003
1N4003
1N4004
1N4004
1N4004
1N4004
R21 (10%, 1 W)
39
39
39
39
39
39
39
39
R22, 23 (10%, 1/2 W)
18
18
18
18
18
18
18
18
2N6397
2N6403
—
R24
SEE TEXT
SCR21, 22
Plastic
2N6240
LL
2N6397
2N6402
—
2N6240
commutating dv/dt. Other advantages are the improved
thermal and surge characteristics of having two devices; the
disadvantage is increased cost.
The SCR power circuit can use the same control circuit as
the TRIAC Circuit shown in Figure 6.39(a). In Figure 6.42,
for positive load terminal and when the control circuit is
gated on, current flows through the load, D21, R21, SCR1,
D22, the gate of SCR21 and back to the line, thus turning on
SCR21. Operation is similar for the other line polarity. R22
and R23 provide a path for the off-state leakage of the
control circuit and are chosen so that the voltage dropped
across them is less than the VGT(MIN) of the particular SCR.
R24 and C21 provide snubbing and line transient suppression, and may be chosen from Table 6.4 or from the C11,
R13 rows of Table 6.3. The latter values will provide less
transient protection but also less off-state current, with the
capacitor being smaller. Other circuit values are shown in
Table 6.46.
LOAD
RL
RS
CS
Figure 6.41. TRIAC with Snubber Network
SCR SSR CIRCUIT
The inverse parallel connected Silicon Controlled Rectifier (SCR) pair (shown in Figure 6.42) is less sensitive to
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LOAD
D21
R23
D24
R21
+
INPUT
+
CONTROL
CIRCUIT
(SEE FIGURE 6.39(a)
AND TABLE 6.II)
−
−
SCR22
R24
SCR21
D22
C21
R22
D23
LINE
Figure 6.42. SCR SSR Circuit
adequately over 3 to 33 Vdc and − 40 to +100°C. Note that
though the SSR is protected against damage from improperly connected inputs, the external circuit is not, as D31
acts as a bypass for a wrongly connected input driver.
Consult the individual data sheets for packages and
dissipation, temperature, and surge current limits.
While the SCRs have much higher dv/dt commutation
ability, with inductive loads, attention should be paid to
maintaining the dv/dt below data sheet levels.
+
ALTERNATE INPUT CIRCUITS
OC1
CMOS COMPATIBLE
The 1 kΩ resistor, R1, shown in Figure 6.39(a) and
Table 6.2, provide an input that is compatible with the
current that a TTL gate output can sink. The resistor R1
must be changed for CMOS compatibility, aiming at 2 mA
in the LED for adequate performance to 100°C. At 2 mA
do not use the CMOS output for any other function, as a
LOGIC 0 or 1 may not be guaranteed. Assume a forward
voltage drop of 1.1 V for the LED, and then make the
Ohm’s Law calculation for the system dc supply voltage,
thus defining a new value for R1.
R31
330 k
INPUT
Q32
D31
1N4001
2N6427
Q31
MPS5172
TTL/CMOS COMPATIBLE
TH31 WESTERN THERMISTOR
CORP., CURVE 2,
650 Ω ± 10% @ 25°C
P/N2C6500 OR
EQUIVALENT
R33
180
To be TTL compatible at 5 Volts and CMOS compatible
over 3 to 15 Volts, a constant current circuit is required,
such as the one in Figure 6.43. The current is set by the VBE
of Q31 and the resistance of the R32, R33, and thermistor
TH31 network, and is between 1 and 2 mA, higher at high
temperatures to compensate for the reduced transmission
efficiency of optoelectronic-couplers at higher temperature. The circuit of Figure 6.43 gives an equivalent
impedance of approximately 50 kΩ. The circuit performs
R32
330
TH31
−
Figure 6.43. TTL/CMOS Compatible Input
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AC LINE COMPATIBLE
state relays, lamp drivers, motor controls, sensing and
detection circuits; just about any industrial full-wave
application. But in high-frequency applications or those
requiring high voltage or current, their role is limited by
their present physical characteristics, and they become very
expensive at current levels above 40 amperes rms.
SCRs can be used in an inverse-parallel connection to
bypass the limitations of a TRIAC. A simple scheme for
doing this is shown in Figure 6.45. The control device can
take any of many forms, shown is the reed relay (Figure 6.45). TRIACs and Opto couplers can be inserted at
point A−A to replace the reed relay.
To use SSRs as logic switching elements is inefficient,
considering the availability and versatility of logic
families such as CMOS. When it is convenient to trigger
from ac, a circuit such as shown in Figure 6.44 may be
used. The capacitor C41 is required to provide current to
the LED of OC1 through the zero-crossing time. An
in-phase input voltage gives the worst case condition. The
circuit gives 2 mA minimum LED current at 75% of
nominal line voltage.
INVERSE PARALLEL SCRs FOR POWER
CONTROL
TRIACs are very useful devices. They end up in solid
R42
R41
2 kΩ, 10%
1/2 W
2 μF
10%
50 V
C41
BR41
R41
120 V
240 V
OC1
INPUT AC
22 kΩ, 10%, 1 W
47 kΩ, 10%, 2 W
Figure 6.44. AC Compatible Input
Compared to a TRIAC, an inverse-parallel configuration
has distinct advantages. Voltage and current capabilities are
dependent solely on SCR characteristics with ratings today
of over a thousand volts and several hundred amps.
Because each SCR operates only on a half-wave basis, the
system’s rms current rating is 2 times the SCR’s rms
current rating (see Suggested SCR chart). The system has
the same surge current rating as the SCRs do. Operation at
400 Hz is also no problem. While turn-off time and dv/dt
limits control TRIAC operating speed, the recovery
characteristics of an SCR need only be better than the
appropriate half-wave period.
FLOATING
LOAD RL
R
2 V
(R L R C)
I GP
WHERE IGP IS
PEAK GATE
CURRENT
RATING OF SCR
IG1
ILa
a
b
2V
1
SCR1
OR
IG
A
2
A
RC
R
SCR2
CONTROL DEVICE
(CLOSED RESISTANCE)
IG2
GROUNDED
LOAD RL
Figure 6.45. Use of Inverse Parallel SCRs
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ILb
alternately pass the gate currents IG1 and IG2 during the
“a” and “b” half cycles, respectively. ILa and ILb are the
load currents during the corresponding half cycles. Each
SCR then gets the other half cycle for recovery time. Heat
sinking can also be done more efficiently, since power is
being dissipated in two packages, rather than all in one.
The load can either be floated or grounded. the SCRs are
not of the shunted-gate variety, a gate-cathode resistance
should be added to shunt the leakage current at
higher temperatures. The diodes act as steering diodes so
the gate-cathode junctions are not avalanched. The
blocking capability of the diodes need only be as high as
the VGT of the SCRs. A snubber can also be used if
conditions dictate.
With inductive loads you no longer need to worry about
commutating dv/dt, either. SCRs only need to withstand
static dv/dt, for which they are typically rated an order of
magnitude greater than TRIACs are for commutating dv/dt.
Better reliability can be achieved by replacing the reed
relay with a low current TRIAC to drive the SCRs,
although some of its limitations come with it. In the
preferred circuit of Figure 6.46(b), the main requirements
of the TRIAC are that it be able to block the peak system
voltage and that it have a surge current rating compatible
with the gate current require-ments of the SCRs. This is
normally so small that a TO-92 cased device is adequate to
drive the largest SCRs.
In circuits like Figure 6.45, the control devices
A
A
A
A
A
GATE
CONTROL
GATE
CONTROL
(FLOATING)
GATE
CONTROL
(a). Reed Relay
A
(b). Low-Current TRIAC
(c). Optically Coupled TRIAC Driver
Figure 6.46. Control Devices
the power circuit (see Figure 6.46(c)). Table 6.6. lists
suggested components. Another benefit is being able to
gate the TRIAC with a supply of either polarity. Probably
the most important benefit of the TRIAC/SCR combination
is its ability to handle variable-phase applications — nearly
impossible for non solid-state control devices.
This circuit offers several benefits. One is a considerable
increase in gain. This permits driving the TRIAC with
almost any other semiconductors such as linear ICs,
photosensitive devices and logic, including MOS. If
necessary, it can use an optically coupled TRIAC driver to
isolate (up to 7500 V isolation) delicate logic circuits from
Table 6.6. Driver TRIACs
Line
Voltage
Gate Negative Or
In Phase With
Line Voltage
Gate
Positive
Optically
Coupled
120
220
MAC97A4
MAC97A6
MAC97A4
MAC97A6
MOC3030*, 3011
MOC3020, MOC3021
*Includes inhibit circuit for zero crossover firing.
INTERFACING DIGITAL CIRCUITS TO
THYRISTOR CONTROLLED AC LOADS
with quadrants II and III (gate signal negative and MT2
either positive or negative) being the most sensitive and
quadrant IV (gate positive, MT2 negative) the least
sensitive.
For driving a TRIAC with IC logic, quadrants II and III
are particularly desirable, not only because less gate trigger
current is required, but also because IC power dissipation is
reduced since the TRIAC can be triggered by an “active
low” output from the IC.
Because they are bidirectional devices, TRIACs are the
most common thyristor for controlling ac loads. A TRIAC
can be triggered by either a positive or negative gate signal
on either the positive or negative half-cycle of applied MT2
voltage, producing four quadrants of operation. However,
the TRIAC’s trigger sensitivity varies with the quadrant,
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TTL-TO-THYRISTOR INTERFACE
There are other advantages to operating in quadrants II
and III. Since the rate of rise of on-state current of a TRIAC
(di/dt) is a function of how hard the TRIAC’s gate is turned
on, a given IC output in quadrants II and III will produce a
greater di/dt capability than in the less sensitive quadrant
IV. Moreover, harder gate turn-on could reduce di/dt
failure. One additional advantage of quadrant II and III
operation is that devices specified in all four quadrants are
generally more expensive than devices specified in quadrants I, II and III, due to the additional testing involved and
the resulting lower yields.
The subject of interfacing requires a knowledge of the
output characteristics of the driving stages as well as the
input requirements of the load. This section describes the
driving capabilities of some of the more popular TTL
circuits and matches these to the input demands of
thyristors under various practical operating conditions.
A
USING TRIACs
Two important thyristor parameters are gate trigger
current (IGT) and gate trigger voltage (VGT).
IGT (Gate Trigger Current) is the amount of gate trigger
current required to turn the device on. IGT has a negative
temperature coefficient — that is, the trigger current
required to turn the device on increases with decreasing
temperature. If the TRIAC must operate over a wide
temperature range, its IGT requirement could double at the
low temperature extreme from that of its 25°C rating.
It is good practice, if possible, to trigger the thyristor
with three to ten times the IGT rating for the device. This
increases its di/dt capability and ensures adequate gate
trigger current at low temperatures.
VGT (Gate Trigger Voltage) is the voltage the thyristor
gate needs to ensure triggering the device on. This voltage
is needed to overcome the input threshold voltage of the
device. To prevent thyristor triggering, gate voltage should
be kept to approximately 0.4 V or less.
Like IGT, VGT increases with decreasing temperature.
LOAD
60 Hz
LINE
MT2
GATE
VOLTAGE
APPLIED
TO TERMINALS
A AND B
MT1
B
TRIAC
CURRENT
A
t1
t2
IGT
TRIAC
VOLTAGE
WITH SNUBBER
NETWORK
INDUCTIVE LOAD SWITCHING
Switching of inductive loads, using TRIACs, may
require special consideration in order to avoid false
triggering. This false-trigger mechanism is illustrated in
Figure 6.47 which shows an inductive circuit together with
the accompanying waveforms.
As shown, the TRIAC is triggered on, at t1, by the
positive gate current (IGT). At that point, TRIAC current
flows and the voltage across the TRIAC is quite low since
the TRIAC resistance, during conduction, is very low.
From point t1 to t2 the applied IGT keeps the TRIAC in a
conductive condition, resulting in a continuous sinusoidal
current flow that leads the applied voltage by 90° for this
pure inductive load.
At t2, IGT is turned off, but TRIAC current continues to
flow until it reaches a value that is less than the sustaining
current (IH), at point A. At that point, TRIAC current is cut
off and TRIAC voltage is at a maximum. Some of that
voltage is fed back to the gate via the internal capacitance
(from MT2 to gate) of the TRIAC.
CHANGE IN
TRIAC VOLTAGE DURING
TURN-OFF (dv)
toff(dt)
TRIAC
VOLTAGE
WITH SNUBBER
NETWORK
UNDESIRED TRIGGERING
DUE TO FEEDBACK
Figure 6.47. Inductive Load TRIAC Circuit and
Equivalent Waveforms
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TTL CIRCUITS WITH TOTEM-POLE OUTPUTS
(e.g. 5400 SERIES)
VCC
VCC
The configuration of a typical totem-pole connected TTL
output stage is illustrated in Figure 6.48(a). This stage is
capable of “sourcing” current to a load, when the load is
connected from Vout to ground, and of “sinking” current
from the load when the latter is connected from Vout to
VCC. If the load happens to be the input circuit of a TRIAC
(gate to MT1), the TRIAC will be operating in quadrants I
and IV (gate goes positive) when connected from Vout to
ground, and of “sinking” II and III (gate goes negative)
when connected from Vout to VCC.
LOAD
CONNECTION
FOR
CURRENT
SINK
CONDITION
SOURCE
CURRENT
R2
SINK
100
CURRENT
Q2
R1
1.4 k
Vin
TTL
GATE
Vout
Q1
Q3
1k
QUADRANT I-IV OPERATION
Considering first the gate-positive condition,
Figure 6.48(b), the operation of the circuit is as follows:
When Vin to the TTL output stage is low (logical “zero”),
transistors Q1 and Q3 of that stage are cut off, and Q2 is
conducting. Therefore, Q2 sources current to the thyristor,
and the thyristor would be triggered on during the Vin = 0
condition.
When Vin goes high (logical “one”), transistors Q1 and
Q3 are on and Q2 is off. In this condition depicted by the
equivalent circuit transistor Q3 is turned on and its
collector voltage is, essentially, VCE(sat). As a result, the
TRIAC is clamped off by the low internal resistance of Q3.
LOAD
CONNECTION
FOR
CURRENT
SOURCE
CONDITION
Vin
Vout
SOURCE
CURRENT
SINK CURRENT
(a)
VCC
QUADRANT II-III OPERATION
When the TRIAC is to be operated in the more sensitive
quadrants II and III (negative-gate turn-on), the circuit in
Figure 6.49(a) may be employed.
With Q3 in saturation, as shown in the equivalent circuit
of 6.49(b), its saturation voltage is quite small, leaving
virtually the entire − VEE voltage available for thyristor
turn-on. This could result in a TRIAC gate current that
exceeds the current limit of Q3, requiring a current-limiting
series resistor, (R(Iim)).
When the Vout level goes high, Q3 is turned off and Q2
becomes conductive. Under those conditions, the TRIAC
gate voltage is below VGT and the TRIAC is turned off.
R1
R2
TRIAC
LOAD
Q2
60 Hz
Vout
GATE
MT1
(b)
DIRECT-DRIVE LIMITATIONS
With sensitive-gate TRIACs, the direct connection of a
TRIAC to a TTL circuit may sometimes be practical.
However, the limitations of such circuits must be
recognized.
For example:
For TTL circuits, the “high” logic level is specified as
2.4 volts. In the circuit of Figure 6.48(a), transistor Q2 is
capable of supplying a short-circuit output current (ISC) of
20 to 55 mA (depending on the tolerances of R1 and R2,
and on the hFE of Q2). Although this is adequate to turn a
sensitive-gate TRIAC on, the specified 2.4 volt (high) logic
level can only be maintained if the sourcing current is held
to a maximum of 0.4 mA — far less than the current
required to turn on any thyristor. Thus, the direct connection is useful only if the driver need not activate other logic
circuits in addition to a TRIAC.
R1
TRIAC
LOAD
Q1
Vout
60 Hz
Q3
1k
(c)
Figure 6.48. Totem-Pole Output Circuit TTL Logic,
Together with Voltage and Current Waveforms,
(b) Equivalent Circuit for Triggering TRIAC with a
Positive Voltage — TRIAC-On Condition,
(c) TRIAC-Off Condition
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In practice, a 270 Ω, 1/4 W resistor may be used.
A similar limiting condition exists in the Logic “0”
condition of the output, when the thyristor is to be clamped
off. In this condition, Q3 is conducting and Vout equals the
saturation voltage (VCE(sat)) of Q3. TTL specifications
indicate that the low logic level (logic “0”) may not exceed
0.4 volts, and that the sink current must be limited to 16
mA in order not to exceed this value. A higher value of sink
current would cause (VCE(sat)) to rise, and could trigger the
thyristor on.
R(lim)
LOGIC CIRCUIT
MT2
Where a 5400-type TTL circuit is used solely for
controlling a TRIAC, with positive-gate turn-on (quadrants
I-IV), a sensitive gate TRIAC may be directly coupled to
the logic output, as in Figure 6.48. If the correct logic levels
must be maintained, however, a couple of resistors must be
added to the circuit, as in Figure 6.50(a). In this diagram,
R1 is a pull-up which allows the circuit to source more
current during a high logical output. Its value must be large
enough, however, to limit the sinking current below the
16 mA maximum when Vout goes low so that the logical
zero level of 0.4 volts is not exceeded.
Resistor R2, a voltage divider in conjunction with R1,
insures VOH (the “high” output voltage) to be 2.4 V or
greater.
For a supply voltage of 5 V and a maximum sinking
current of 16 mA
CC
(a)
−5V
Isink
R1
Vout
R(lim)
Q3
R
R R
1 2
VCC
CC
–V
)
I
GT
sink
VCC
1.4
(2.6
3.30) 175 W
LOAD
Vout
R1
MT2
R1
60 Hz
LINE
Vout = 2.4 V
R2
R2
1
(V
(b)
Figure 6.49. TTL Circuit for Quadrant II and III TRIAC
Operation Requiring Negative VGT, (b) Schematic
Illustrates TRIAC Turn-On Condition,
Vout = Logical “0”
LOGIC CIRCUIT
When the TRIAC is to be turned on by a negative gate
voltage, as in Figure 6.49(b), the purpose of the limiting
resistor R(Iim) is to hold the current through transistor Q3 to
16 mA. With a 5 V supply, a TRIAC VGT of 1 V and a
maximum sink current of 16 mA
(lim)
MT2
60 Hz
LINE
LOAD
−5V
A 180 Ω resistor may be used for R2. If the VGT is less
than 1 volt, R2 may need to be larger.
The MAC97A and 2N6071A TRIACs are compatible
devices for this circuit arrangement, since they are
guaranteed to be triggered on by 5 mA, whereas the current
through the circuit of Figure 6.50(b) is approximately
8 mA, (V R R 1).
R
VEE(sat)
0.4 V MAX
1k
16 mA 5
0.016 312 W
1.4
V
MT1
Q1
Thus, 330 Ω, 1/4 W resistor may be used. Assuming R1 to
be 330 Ω and a thyristor gate on voltage (VGT) of 1 V, the
equivalent circuit of Figure 6.49(b) exists during the logical “1” output level. Since the logical “1” level must be
maintaned at 2.4 volts, the voltage drop across R2 must be
1.4 V. Therefore,
R 2 1.4
I
60 Hz
LINE
LOAD
CIRCUIT DESIGN CONSIDERATIONS
R1 V
MT1
MT1
G=1V
(a)
(b)
Figure 6.50. Practical Direct-Coupled TTL
TRIAC Circuit, (b) Equivalent Circuit Used for
Calculation of Resistor Values
(5–1)(0.016250 W
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OPEN COLLECTOR TTL CIRCUIT
Circuits utilizing Schottky TTL are generally designed in
the same way as TTL circuits, although the current
source/sink capabilities may be slightly different.
The output section of an open-collector TTL gate is
shown in Figure 6.51(a).
A typical logic gate of this kind is the 5401 type
Q2-input NAND gate circuit. This logic gate also has a
maximum sink current of 16 mA (VOL = 0.4 V max.)
because of the Q1 (sat) limitations. If this logic gate is to
source any current, a pull-up-collector resistor, R1 (6.51b)
is needed. When this TTL gate is used to trigger a thyristor,
R1 should be chosen to supply the maximum trigger current
available from the TTL circuit ( 16 mA, in this case).
The value of R1 is calculated in the same way and for the
same reasons as in Figure 6.50. If a logical “1” level must
be maintained at the TTL output (2.4 V min.), the entire
circuit of Figure 6.50 should be used.
For direct drive (logical “0”) quadrants II and III
triggering, the open collector, negative supplied ( −5 V)
TTL circuit of Figure 6.52 can be used. Resistor R1 can
have a value of 270 Ω, as in Figure 6.49. Resistor R2
ensures that the TRIAC gate is referenced to MT1 when the
TTL gate goes high (off), thus preventing unwanted
turn-on. An R2 value of about 1 k should be adequate for
sensitive gate TRIACs and still draw minimal current.
R2
MT2
R1
60 Hz
LINE
LOAD
LOGIC CIRCUIT
−5V
Figure 6.52. Negative-Supplied ( −5 V) TTL Gate
Permits TRIAC Operation in Quadrants II and III
TRIGGERING THYRISTORS FROM LOGIC GATES
USING INTERFACE TRANSISTORS
For applications requiring thyristors that demand more
gate current than a direct-coupled logic circuit can supply,
an interface device is needed. This device can be a
small-signal transistor or an opto coupler.
The transistor circuits can take several different configurations, depending on whether a series or shunt switch
design is chosen, and whether gate-current sourcing
(quadrants I and IV) or sinking (quadrants II and III) is
selected. An example of a series switch, high output (logic
1) activation, is shown in Figure 6.53. Any logic family can
be used as long as the output characteristics are known.
The NPN interface transistor, Q1, is configured in the
common-emitter mode — the simplest approach — with
the emitter connected directly to the gate of the thyristor.
VCC
1.4 k
TTL
GATE
MT1
G
Vout
Q1
1k
(a)
5V
VCC
LOAD
MT2
R1
LOAD
60 Hz
LINE
R4
R1
Vout
MT2
G
R2
Q1
MT1
LOGIC CIRCUIT
60 Hz
LINE
G
LOGIC GATE
R3
(b)
Figure 6.51. Output Section of Open-Collector TTL,
(b) For Current Sourcing, A Pull-up Resistor, R1,
Must Be Added
MT1
R5
Figure 6.53. Series Switch, High Output (Logic “1”)
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When thyristor operation in quadrants II and III is
desired, the circuits of Figures 6.55 and 6.56 can be used;
Figure 6.55 is for high logic output activation and
Figure 6.56 is for low. Both circuits are similar to those on
Figures 6.53 and 6.54, but with the transistor polarity and
power supplies reversed.
Depending on the logic family used, resistor R1 (pull-up
resistor) and R3 (base-emitter leakage resistor) may or may
not be required. If, for example, the logic is a typical TTL
totem-pole output gate that must supply 5 mA to the base of
the NPN transistor and still maintain a “high” (2.4 V) logic
output, then R1 and R2 are required. If the “high” logic
level is not required, then the TTL circuit can directly
source the base current, limited by resistor R2.
To illustrate this circuit, consider the case where the
selected TRIAC requires a positive-gate current of
100 mA. The interface transistor, a popular 2N4401, has a
specified minimum hFE (at a collector current of 150 mA)
of 100. To ensure that this transistor is driven hard into
saturation, under “worse case” (low temperature) conditions, a forced hFE of 20 is chosen — thus, 5 mA of base
current. For this example, the collector supply is chosen to
be the same as the logic supply (+5 V); but for the circuit
configuration, it could be a different supply, if required.
The collector-resistor, R4, is simply
+5V
LOAD
R2
MT2
R1
Q1
60 Hz
LINE
R3
G
LOGIC GATE
MT1
R4
R 4 (V CC V CE(sat) V GT(typ))
I GT
Figure 6.54. Low-Logic Activation with
Interface Transistor
(5 1 0.9)
100 mA 40 W
A 39 ohm, 1 W resistor is then chosen, since its actual
dissipation is about 0.4 W.
If the “logic 1” output level is not important, then the
base limiting resistor R2 is required, and the pull-up
resistor R1 is not. Since the collector resistor of the TTL
upper totem-pole transistor, Q2, is about 100 Ω, this
resistor plus R2 should limit the base current to 5 mA.
Thus R2 calculates to
R1
R5
R4
R2
G
MT1
Q1
LOGIC GATE
MT2
60 Hz
LINE
R3
LOAD
R 2 [(V CC V BE V GT)
5 mA] 100 W
[(5 0.7 0.9)
0.005] 100 W
560 W (specified)
− VEE
Figure 6.55. High-Logic Output Activation
When the TTL output is low, the lower transistor of the
totem-pole, Q3, is a clamp, through the 560 Ω resistor,
across the 2N4401; and, since the 560 Ω resistor is relatively
low, no leakage-current shunting resistor, R3, is required.
In a similar manner, if the TTL output must remain at
“logic 1” level, the resistor R1 can be calculated as
described earlier (R3 may or may not be required).
For low-logic activation (logic “0”), the circuit of
Figure 6.54 can be used. In this example, the PNP-interface
transistor 2N4403, when turned on, will supply positivegate current to the thyristor. To ensure that the high logic
level will keep the thyristor off, the logic gate and the
transistor emitter must be supplied with the same power
supply. The base resistors, as in the previous example, are
dictated by the output characteristics of the logic family
used. Thus if a TTL gate circuit is used, it must be able to
sink the base current of the PNP transistor (IOL(MAX) =
16 mA).
Figure 6.55 sinks current from the thyristor gate
through a switched NPN transistor whose emitter is
referenced to a negative supply. The logic circuit must also
be referenced to this negative supply to ensure that
transistor Q1 is turned off when required; thus, for TTL
gates, VEE would be −5 V.
In Figure 6.56, the logic-high bus, which is now ground, is
the common ground for both the logic, and the thyristor and
the load. As in the first example (Figure 6.53), the negative
supply for the logic circuit (−VEE) and the collector supply
for the PNP transistor need not be the same supply. If, for
power-supply current limitations, the collector supply is
chosen to be another supply (−VCC), it must be within the
VCEO ratings of the PNP transistor. Also, the power
dissipation of collector resistor, R3, is a function of −VCC —
the lower −VCC, the lower the power rating.
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R2
R4
The four examples shown use gate-series switching to
activate the thyristor and load (when the interface transistor
is off, the load is off). Shunt-switching can also be used if
the converse is required, as shown in Figures 6.57 and 6.58.
In Figure 6.57, when the logic output is high, NPN
transistor, Q1, is turned on, thus clamping the gate of the
thyristor off. To activate the load, the logic output goes low,
turning off Q1 and allowing positive gate current, as set by
resistor R3, to turn on the thyristor.
In a similar manner, quadrant’s II and III operation is
derived from the shunt interface circuit of Figure 6.58.
MT1
G
R1
LOGIC GATE
MT2
60 Hz
LINE
R3
LOAD
OPTICAL ISOLATORS/COUPLERS
An Optoelectronic isolator combines a light-emitting
device and a photo detector in the same opaque package
that provides ambient light protection. Since there is no
electrical connection between input and output, and the
emitter and detector cannot reverse their roles, a signal can
pass through the coupler in one direction only.
Since the opto-coupler provides input circuitry protection and isolation from output-circuit conditions, groundloop prevention, dc level shifting, and logic control of high
voltage power circuitry are typical areas where optocouplers are useful.
Figure 6.59 shows a photo-TRIAC used as a driver for a
higher-power TRIAC. The photo-TRIAC is light sensitive
and is turned on by a certain specified light density (H),
which is a function of the LED current. With dark
conditions (LED current = 0) the photo-TRIAC is not
turned on, so that the only output current from the coupler
is leakage current, called peak-blocking current (IDRM).
The coupler is bilateral and designed to switch ac signals.
The photo-TRIAC output current capability is, typically,
100 mA, continuous, or 1 A peak.
− VEE
Figure 6.56. Low-Logic Output Activation
+5V
LOAD
R3
MT2
R1
Q1
LOGIC GATE
60 Hz
LINE
G
R2
MT1
Figure 6.57. Shunt-Interface Circuit (High-Logic Output)
G
R2
MT1
R
I
MT2
H
R1
MT2
LOGIC GATE
R3
LED
60 Hz
LINE
PHOTO
TRIAC
G
MT1
60 Hz
LINE
OPTO COUPLER
LOAD
LOAD
− VEE
Figure 6.59. Optically-Coupled TRIAC Driver is Used
to Drive a Higher-Power TRIAC
Figure 6.58. Shunt-Interface Circuit
(Quadrants I and III Operation)
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I OH 300 mA (V OH 2.4 V)
Any Opto TRIAC can be used in the circuit of
Figure 6.59 by using Table 6.8. The value of R is based on
the photo-TRIAC’s current-handling capability. For
example, when the MOC3011 operates with a 120 V line
voltage (approximately 175 V peak), a peak IGT current of
175 V/180 ohm (approximately 1 A) flows when the line
voltage is at its maximum. If less than 1 A of IGT is needed,
R can be increased. Circuit operation is as follows:
I OL 1.8 mA (V OL 0.4 V)
V CC 5 V
Since this is not adequate for driving the optocoupler
directly (10 mA for the MOC3011), an interface transistor
is necessary.
The circuit of Figure 6.60 may be used for thyristor
triggering from the 3870 logical “1.”
+5V
Table 6.8. Specifications for Typical Optically
Coupled TRIAC Drivers
R3
Device
Type
Maximum Required
LED Trigger
Current (mA)
Peak
Blocking
Voltage
R(Ohms)
MOC3011
MOC3011
MOC3021
MOC3031
15
10
15
15
250
250
400
250
180
180
360
51
R
MT2
R1
60 Hz
LINE
G
MT1
R2
When an op-amp, logic gate, transistor or any other
appropriate device turns on the LED, the emitted light
triggers the photo-TRIAC. Since, at this time, the main
TRIAC is not on, MT2-to-gate is an open circuit. The
60 Hz line can now cause a current flow via R, the
photo-TRIAC, Gate-MT1 junction and load. This
Gate-MT1 current triggers the main TRIAC, which then
shorts and turns off the photo-TRIAC. The process repeats
itself every half cycle until the LED is turned off.
Triggering the main TRIAC is thus accomplished by
turning on the LED with the required LED-trigger current
indicated in Table 6.7.
Q1
LOAD
MC3870
Figure 6.60. Logical “1” Activation from MC3870P
Microcomputer
The interface transistor, again, can be the 2N4401. With
10 mA of collector current (for the MOC3011) and a base
current of 0.75 mA, the VCE(sat) will be approximately
0.1 V.
R1 can be calculated as in a previous example.
Specifically:
1.8 mA (maximum I OL for the 3870)
MICROPROCESSORS
5 V
R 1; R 1 2.77 k
R 1 can be 3 k, 1
4 W
Microprocessor systems are also capable of controlling ac
power loads when interfaced with thyristors. Commonly, the
output of the MPU drives a PIA (peripheral interface
adaptor) which then drives the next stage. The PIA Output
Port generally has a TTL compatible output with significantly less current source and sink capability than standard TTL.
(MPUs and PIAs are sometimes constructed together on the
same chip and called microcontrollers.)
When switching ac loads from microcomputers, it is
good practice to optically isolate them from unexpected
load or ac line phenomena to protect the computer
system from possible damage. In addition, optical
isolation will make UL recognition possible.
A typical TTL-compatible microcontroller, such as the
MC3870P offers the following specifications:
With a base current of 0.75 mA, R1 will drop (0.75 mA)
(3 k) or 2.25 V. This causes a VOH of 2.75 V, which is
within the logical “1” range.
R 2 [2.75 V–V BE(on)]
I B (2.75–0.75)
0.75 2.66 k
.
R 2 can be a 2.7 k, 1
4 W resistor.
R 3 must limit I C to 10 mA :
R 3 [5 V–V CE(sat) – V F(diode)
10 mA]
(5–0.1–1.2)
10 mA 370 W
Since R3 is relatively small, no base-emitter leakage
resistor is required.
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As shown in Figure 6.62(a), the output stage of a typical
CMOS Gate consists of a P-channel MOS device connected in series with an N-channel device (drain-to-drain),
with the gates tied together and driven from a common
input signal. When the input signal goes high, logical 1, the
P-channel device is essentially off and conducts only
leakage current (IDSS), on the order of pico-amps. The
N-channel unit is forward-biased and, although it has a
relatively high on resistance (rDS(on)), the drain-to-source
voltage of the N-channel device (VDS) is very low
(essentially zero) because of the very low drain current
(VDSS) flowing through the device. Conversely, when the
input goes low (zero), the P-channel device is turned fully
on, the N-channel device is off and the output voltage will
be very near VDD.
When interfacing with transistors or thyristors, the
CMOS Gate is current-limited mainly by its relatively high
on resistance, the dc resistance between drain and source,
when the device is turned on.
The equivalent circuits for sourcing and sinking current
into an external load is shown in Figures 6.62(b) and
6.62(c). Normally, when interfacing CMOS to CMOS, the
logic outputs will be very near their absolute maximum
states (VDD or 0 V) because of the extremely small load
currents. With other types of loads (e.g. TRIACs), the
current, and the resulting output voltage, is dictated by the
simple voltage divider of rDS(on) and the load resistor RL,
where rDS(on) is the total series and/or parallel resistance of
the devices comprising the NOR and NAND function.
Interfacing CMOS gates with thyristors requires a
knowledge of the on resistance of the gate in the source and
sink conditions. The on-resistance of CMOS devices is not
normally specified on data sheets.
It can easily be calculated, however, from the output
drive currents, which are specified. The drive (source/sink)
currents of typical CMOS gates at various supply voltages
are shown in Table 6.9. From this information, the on
resistance for worst case design is calculated as follows:
For the source condition
Figure 6.61 shows logical “0” activation. Resistor values
are calculated in a similar way.
+5V
R1
R2
Q1
MC3870P
R3
R
MT2
60 Hz
LINE
G
MT1
LOAD
Figure 6.61. Logical “0” Activation
VDD
VDD
VDD
S
P-CHANNEL
rDS(on)
P-CHANNEL
D
Vin
D
Vout
Vout
RL
Vout
N-CHANNEL
RL
N-CHANNEL
rDS(on)
S
(a)
(b)
(c)
Figure 6.62. Output Section of a Typical CMOS Gate,
(b) Equivalent Current-Sourcing Circuit is Activated
when Vin goes Low, Turning the P-Channel Device
Fully On, (c) Equivalent Current Sinking Circuit is
Activated when the Input Goes High and Turns the
N-Channel Device On
r DS(on)(MAX) (V
DD
V
OH
)
I
OH(MIN)
Similarly, for the sink current condition
r DS(on)(MAX) V OL
I OL(MIN)
Values of rDS(on) for the various condition shown in
Table 6.9 are tabulated in Table 6.10.
Specified source/sink currents to maintain logical “1”
and logical “0” levels for various power-supply (VDD)
voltages. The IOH and IOL values are used to calculate the
“on” resistance of the CMOS output.
THE CMOS INTERFACE
Another popular logic family, CMOS, can also be used to
drive thyristors.
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DC MOTOR CONTROL WITH THYRISTORS
Table 6.9. CMOS Characteristics
Output Drive Current
I(source) − IOH
VDD = 5 V; VOH = 2.5 V
VDD = 10 V; VOH = 9.5 V
VDD = 15 V; VOH = 13.5 V
I(sink) − IOL
VDD = 5 V; VOL= 0.4 V
VDD = 10 V; VOL = 0.5 V
VDD = 15 V; VOL = 1.5 V
CMOS AL
Series
mA, dc
In order to control the speed of a dc series field motor at
different required torque levels, it is necessary to adjust the
voltage applied to the motor. For any particular applied
voltage the motor speed is determined solely by the torque
requirements and top speed is reached under minimum
torque conditions. When a series motor is used as a traction
drive for vehicles, it is desirable to control the voltage to
the motor to fit the various torque requirements of grades,
speed and load. The common method of varying the speed
of the motor is by inserting resistance in series with the
motor to reduce the supplied voltage. This type of motor
speed control is very inefficient due to the I2R loss,
especially under high current and torque conditions.
A much more efficient method of controlling the voltage
applied to the motor is the pulse width modulation method
shown in Figure 6.63. In this method, a variable width
pulse of voltage is applied to the motor at the same rate to
proportionally vary the average voltage applied to the
motor. A diode is placed in parallel with the inductive
motor path to provide a circuit for the inductive motor
current and prevent abrupt motor current change. Abrupt
current changes would cause high induced voltage across
the switching device.
CMOSCL/CP
Series
mA, dc
Min
Typ
Min
Typ
− 0.5
− 0.5
− 1.7
− 0.9
− 3.5
− 0.2
− 0.2
− 1.7
− 0.9
− 3.5
0.4
0.9
7.8
2
7.8
0.2
0.5
7.8
2
7.8
Table 6.10. Calculated CMOS On Resistance Values
For Current Sourcing and Sinking
at Various VDD Options
Output Resistance, rDS(on)
Ohms
Operating Conditions
Typical
Maximum
1.7 k
500
430
12.5 k
2.5 k
—
Source Condition
VDD =
5V
10 V
15 V
+
−
Sink Condition
VDD =
5V
10 V
15 V
500
420
190
2k
1k
—
VM
LM
+
− BATTERY
RM
It is apparent from this table that the on resistance
decreases with increasing supply voltage.
Although the minimum currents are now shown on the
data sheet for the 15 V case, the maximum on resistance
can be no greater than the 10 V example and, therefore, can
be assumed for worst case approximation to be 1 and
2.5 kohms for sink-and-source current cases, respectively.
The sourcing on resistance is greater than the sinking
case because the difference in carrier mobilities of the two
channel types.
Since rDS(on) for both source and sink conditions varies
with supply voltage (VDD), there are certain drive
limitations. The relative high rDS(on) of the P-channel
transistor could possibly limit the direct thyristor drive
capability; and, in a like manner, the N-channel rDS(on)
might limit its clamping capability. With a 10 or 15 V
supply, the device may be capable of supplying more than
10 mA, but should be limited to that current, with an
external limiting resistor, to avoid exceeding the reliable
limits of the unit metalization.
VM = BACK EMF
OF MOTOR
LM = MOTOR
INDUCTANCE
RM = MOTOR
RESISTANCE
APPLIED
BATTERY
VOLTAGE
BATTERY
CURRENT
DIODE
CURRENT
MOTOR
CURRENT
AVERAGE
AVERAGE
AVERAGE
AVERAGE
Figure 6.63. Basic Pulse Width Modulated
Motor Speed Control
The circulating current through the diode decreases only
in response to motor and diode loss. With reference to
Figure 6.63, it can be seen that the circulating diode current
causes more average current to flow through the motor than
is taken from the battery. However, the power taken from
the battery is approximately equal to the power delivered to
the motor, indicating that energy is stored in the motor
inductance at the battery voltage level and is delivered to
the motor at the approximate current level when the battery
is disconnected.
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mately 55 μF. In this circuit, SCR3 is gated on at the same
time as SCR1 and allows the resonant charging of Cc
through Lc to twice the supply voltage. SCR3 is then turned
off by the reversal of voltage in the resonant circuit before
SCR2 is gated on. It is apparent that there is very little
power loss in the charge circuit depending upon the voltage
drop across SCR3 and the resistance in Lc.
To provide smooth and quiet motor operation, the current
variations through the motor should be kept to a minimum
during the switching cycle. There are limitations on the
amount of energy that can be stored in the motor
inductance, which, in turn, limits the power delivered to the
motor during the off time; thus the off time must be short.
To operate the motor at low speeds, the on time must be
approximately 10 percent of the off time and therefore, a
rapid switching rate is required that is generally beyond the
capabilities of mechanical switches. Practical solutions can
be found by the use of semiconductor devices for fast,
reliable and efficient switching operations.
R1
Cc
SCR DC MOTOR CONTROL
SCRs offer several advantages over power transistors
as semiconductor switches. They require less driver
power, are less susceptible to damage by overload
currents and can handle more voltage and current. Their
disadvantages are that they have a higher power
dissipation due to higher voltage drops and the difficulty
in commutating to the off condition.
The SCR must be turned off by either interrupting the
current through the anode-cathode circuit or by forcing
current through the SCR in the reverse direction so that the
net flow of forward current is below the holding current
long enough for the SCR to recover blocking ability.
Commutation of the SCR in high current motor control
circuits is generally accomplished by discharging a capacitor through the SCR in the reverse direction. The value of
this capacitor is determined approximately from the
following equation:
Cc SCR1
SCR2
Figure 6.64. Speed Control with Resistive Charging
Lc
SCR3
Cc
SCR1
Tq I
Where:
Cc =
Tq =
IA =
Vc =
TRIGGER
CIRCUIT
TRIGGER
CIRCUIT
SCR2
Figure 6.65. Speed Control with Inductive Charging
A
Vc
value of necessary commutating capacitance
turn-off time of the SCR
value of anode current before commutation
voltage of Cc before commutation
D2
D1
This relationship shows that to reduce the size of Cc, the
capacitor should be charged to as high a voltage as possible
and the SCR should be selected with as low a turn-off time
as possible.
If a 20 microsecond turn-off time SCR is commutated by
a capacitor charged to 36 volts, it would take over 110 μF to
turn off 200 amperes in the RC commutating circuit of
Figure 6.64. If a 50 cycle switching frequency is desired, the
value of R1 would be approximately 5 ohms to allow
charging time with an on duty cycle of 10 percent. The value
of this resistor would give approximately 260 watts dissipation in the charging circuit with 90 percent off duty cycle.
If the resonant charging commutating circuitry of
Figure 6.65 is used, the capacitor is reduced to approxi-
TRIGGER
CIRCUIT
SCR1
SCR2
Figure 6.66. SCR Motor Control with Transformer
Charging
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To obtain the 6 V bias, the 36 V string of 6 V batteries are
tapped, as shown in the schematic. Thus, the motor is
powered from 30 V and the collector supply for Q2 is 24 V,
minimizing the dissipation in colllector load resistor R1.
Total switching loss in switchmode applications is the
result of the static (on-state) loss, dynamic (switching) loss
and leakage current (off-state) loss. The low saturation
voltage of germanium transistors produces low static loss.
However, switching speeds of the germanium transistors
are low and leakage currents are high. Loss due to leakage
current can be reduced with off bias, and load line shaping
can minimize switching loss. The turn-off switching loss
was reduced with a standard snubber network (D5, C1, R2)
see Figure 6.67.
Turn-on loss was uniquely and substantially reduced by
using a parallel connected SCR (across the germanium
transistors) the MCR265-4 (55 A rms, 550 A surge). This
faster switching device diverts the initial turn-on motor load
current from the germanium output transistors, reducing
both system turn-on loss and transistor SOA stress.
The main point of interest is the power switching portion of
the PWM motor controller. Most of the readily available
PWM ICs can be used (MC3420, MC34060, TL494,
SG1525A, UA78S40, etc.), as they can source at least a
10 mA, +15 V pulse for driving the following power
MOSFET.
If the commutating capacitor is to be reduced further, it is
necessary to use a transformer to charge the capacitor to
more than twice the supply voltage. This type of circuit is
illustrated by the transformer charge circuit shown in
Figure 6.66. In this circuit the capacitor can be charged to
several times the supply voltage by transformer action
through diode D1 before commutating SCR1. The disadvantage of this circuit is in the high motor current that
flows through the transformer primary winding.
HEAVY DUTY MOTOR CONTROL WITH SCRs
Another advantage of SCRs is their high surge current
capabilities, demonstrated in the motor drive portion of the
golf cart controller shown in Figure 6.67. Germanium
power transistors were used because of the low saturation
voltages and resulting low static power loss. However,
since switching speeds are slow and leakage currents are
high, additional circuit techniques are required to ensure
reliable operation:
1. The faster turn-on time of the SCR (Q9) over that
of the germanium transistors shapes the turn-on load
line.
2. The parallelled output transistors (Q3-Q8) require a
6 V reverse bias.
3. The driver transistor Q2 obtains reverse bias by
means of diode D4.
+ 36 V
OFF BIAS
6
25 W
Q3
27
1N1183
D4
Q9
MCR
265-4
Q8
(6) MATCHED
700 μF
C1
D5
+ 30 V
1
R2
+ 24 V
+ 15 V
20
50 W
R1
+10 μF
25 V
0.01 μF
Q2
1 μF
D2
330
0.6
200 W
1N1183
1N914
D1
470
+ 18 V
(2)
D3
1N4744
1N914
FORWARD REVERSE
PWM
1k
UTC
H51
10 k
dc
MOTOR
2 HP
Q1
MTP12N10E
SENSE
CURRENT
TO PWM
0.001
Figure 6.67. PWM DC Motor Controller Using SCR Turn-On Feature
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+ 15 V
Although a series-wound motor can be used with either
dc or ac excitation, dc operation provides superior performance. A universal motor is a small series-wound motor
designed to operate from either a dc or an ac supply of the
same voltage. In the small motors used as universal motors,
the winding inductance is not large enough to produce
sufficient current through transformer action to create
excessive commutation problems. Also, high-resistance
brushes are used to aid commutation. The characteristics of
a universal motor operated from alternating current closely
approximate those obtained for a dc power source up to full
load; however, above full load the ac and dc characteristics
differ. For a series motor that was not designed as a
universal motor, the speed-torque characteristic with ac
rather than dc is not as good as that for the universal motor.
At eight loads, the speed for ac operation may be greater
than for dc since the effective ac field strength is smaller
than that obtained on direct current. At any rate, a series
motor should not be operated in a no-load condition unless
precaution is are taken to limit the maximum speed.
Due to the extremely high input impedance of the
power MOSFET, the PWM output can be directly
connected to the FET gate, requiring no active interface
circuitry. The positive going output of the PWM is power
gained and inverted by the TMOS FET Q1 to supply the
negative going base drive to PNP transistor Q2. Diode D1
provides off-bias to this paraphase amplifier, the negative
going pulse from the emitter furnishing base drive to the
six parallel connected output transistors and the positive
going collector output pulse supplying the SCR gate trigger
coupled through transformer T1.
Since the faster turn-on SCR is triggered on first, it will
carry the high, initial turn-on motor current. Then the
slower turn-on germanium transistors will conduct clamping off the SCR, and carry the full motor current. For the
illustrated 2HP motor and semiconductors, a peak exponentially rising and falling SCR current pulse of 120 A
lasting for about 60 μs was measured. This current is well
within the rating of the SCR. Thus, the high turn-on
stresses are removed from the transistors providing a much
more reliable and efficient motor controller while using
only a few additional components.
DIRECTION AND SPEED CONTROL
FOR MOTORS
For a shunt motor, a constant voltage should be applied
to the shunt field to maintain constant field flux so that
the armature reaction has negligible effect. When constant
voltage is applied to the shunt field, the speed is a direct
function of the armature voltage and the armature current.
If the field is weak, then the armature reaction may
counterbalance the voltage drop due to the brushes,
windings and armature resistances, with the net result of a
rising speed-load characteristic.
The speed of a shunt-wound motor can be controlled
with a variable resistance in series with the field or the
armature. Varying the field current for small motor
provides a wide range of speeds with good speed regulation. However, if the field becomes extremely weak, a
rising speed-load characteristic results. This method cannot
provide control below the design motor speed. Varying the
resistance in series with the armature results in speeds less
than the designed motor speed; however, this method
yields poor speed regulation, especially at low speed
settings. This method of control also increases power
dissipation and reduces efficiency and the torque since the
maximum armature current is reduced. Neither type of
resistive speed control is very satisfactory. Thyristor drive
controls, on the other hand, provide continuous control
through the range of speed desired, do not have the power
losses inherent in resistive circuits, and do not compromise
the torque characteristics of motors.
SERIES-WOUND MOTORS
The circuit shown in Figure 6.68 can be used to control
the speed and direction of rotation of a series-wound dc
motor. Silicon controlled rectifiers Q1- Q4, which are
connected in a bridge arrangement, are triggered in
diagonal pairs. Which pair is turned on is controlled by
switch S1 since it connects either coupling transformer T1
or coupling transformer T2 to a pulsing circuit. The current
in the field can be reversed by selecting either SCRs Q2
and Q3 for conduction, or SCRs Q1 and Q4 for conduction.
Since the armature current is always in the same direction,
the field current reverses in relation to the armature current,
thus reversing the direction of rotation of the motor.
A pulse circuit is used to drive the SCRs through either
transformer T1 or T2. The pulse required to fire the SCR is
obtained from the energy stored in capacitor C1. This
capacitor charges to the breakdown voltage of zener diode
D5 through potentiometer R1 and resistor R2. As the
capacitor voltage exceeds the zener voltage, the zener
conducts, delivering current to the gate of SCR Q5. This
turns Q5 on, which discharges C1 through either T1 or T2
depending on the position of S1. This creates the desired
triggering pulse. Once Q5 is on, it remains on for the
duration of the half cycle. This clamps the voltage across
C1 to the forward voltage drop of Q5. When the supply
voltage drops to zero, Q5 turns off, permitting C1 to begin
charging when the supply voltage begins to increase.
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D2
D1
AC
LINE
D3
(4) 1N4722
OR
MDA2503
MCR12D
Q1
FIELD
MCR12D
Q3
D4
R1
20 k
5W
MCR12D
Q2
T1
MCR12D
Q4
T1
T2
R2, 4.7 k
5W
5 μF
75 V
+
Q5
2N5062
T2
ARMATURE
C1
D5
1N5262
S1
T1
R3
1k
T2
(2)
SPRAGUE
11Z13
Figure 6.68. Direction and Speed Control for Series-Wound or Universal Motor
ac
LINE
D1
D3
D2
(4) 1N4722
D4
Q3
Q1
R1
20 k
5W
FIELD
5 μF
75 V
R2, 4.7 k
5W
T2
ARMATURE
T1
+
D5 C1
1N5262
Q5
2N5062
R3
1k
Q4
T1
T2
Q2
T1
T2
T1 AND T2 ARE SPRAGUE 11Z13
Q1 THRU Q4 MCR12D
Figure 6.69. Direction and Speed Control for Shunt-Wound Motor
The speed of the motor can be controlled by potentiometer R1. The larger the resistance in the circuit, the longer
required to charge C1 to the breakdown voltage of zener
D5. This determines the conduction angle of either Q1 and
Q4, or Q2 and Q3, thus setting the average motor voltage
and thereby the speed.
Figure 6.69 is required. This circuit operates like the one
shown in Figure 6.68. The only differences are that the
field is placed across the rectified supply and the armature
is placed in the SCR bridge. Thus the field current is
unidirectional but armature current is reversible; consequently the motor’s direction of rotation is reversible.
Potentiometer R1 controls the speed as explained
previously.
SHUNT-WOUND MOTORS
If a shunt-wound motor is to be used, then the circuit in
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RESULTS
With the supply voltage applied to the circuit, the timing
capacitor C1 charges to the firing point of the PUT, 2 volts
plus a diode drop. The output of the PUT is coupled
through two 0.01 μF capacitors to the gate of Q2 and Q3.
To clarify operation, assume that Q3 is on and capacitor C4
is charged plus to minus as shown in the figure. The next
pulse from the PUT oscillator turns Q2 on. This places the
voltage on C4 across Q3 which momentarily reverse biases
Q3. This reverse voltage turns Q3 off. After discharging,
C4 then charges with its polarity reversed to that shown.
The next pulse from Q1 turns Q3 on and Q2 off. Note that
C4 is a non-polarized capacitor.
For the component values shown, the lamp is on for
about 1/2 second and off the same amount of time.
Excellent results were obtained when these circuits were
used to control 1/15 hp, 115 V, 5,000 r/min motors. This
circuit will control larger, fractional-horsepower motors
provided the motor current requirements are within the
semiconductor ratings. Higher current devices will permit
control of even larger motors, but the operation of the
motor under worst case must not cause anode currents to
exceed the ratings of the semiconductor.
PUT APPLICATIONS
PUTs are negative resistance devices and are often used
in relaxation oscillator applications and as triggers for
controlling thyristors. Due to their low leakage current,
they are useful for high-impedance circuits such as
long-duration timers and comparators.
R1
10 k
TYPICAL CIRCUITS
C1
19
R4
2k
C1
10 μF
Q2
2N5060
C2
0.01 μF
R2
910
R5
1k
17
C = 0.0047 μF
16
C = 0.01 μF
Vin (VOLTS)
15
GE NO.
14
14
13
12
11
10
9
(SEE TEXT)
8
7
0.01 μF
C3
5 to 20 V
R4
100
18
+3V
C4
4 μF
+
−
+
Figure 6.71. (a). Voltage Controlled Ramp Generator
(VCRG)
The PUT operates very well at low supply voltages
because of its low on-state voltage drop.
A circuit using the PUT in a low voltage application is
shown in Figure 6.70 where a supply voltage of 3 volts is
used. The circuit is a low voltage lamp flasher composed of
a relaxation oscillator formed by Q1 and an SCR flip flop
formed by Q2 and Q3.
Q1
2N6027
R5
2N6027 100 k
R2
20 k
20
R6
51 k
RAMP OUT
−
40 V
LOW VOLTAGE LAMP FLASHER
R3
1k
Q1
MPS6516
+
The following circuits show a few of the many ways in
which the PUT can be used. The circuits are not optimized
even though performance data is shown.
In several of the circuit examples, the versatility of the
PUT has been hidden in the design. By this it is meant that
in designing the circuit, the circuit designer was able to
select a particular intrinsic standoff ratio or he could select
a particular RG (gate resistance) that would provide a
maximum or minimum valley and peak current. This
makes the PUT very versatile and very easy to design with.
R1
100 k
R3
510 k
Q3
2N5060
6
5
R7
1k
1
2
3
4
5
6
7
DURATION TIME (ms)
(b). Voltage versus Ramp Duration Time of VCRG
Figure 6.70. Low Voltage Lamp Flasher
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8
VOLTAGE CONTROLLED RAMP GENERATOR
discharged but C2 remains charged to 10 volts. As Q1 turns
off this time, C1 and C2 again charge. This time C2 charges
to the peak point firing voltage of the PUT causing it to
fire. This discharges capacitor C2 and allows capacitor
C1 to charge to the line voltage. As soon as C2 discharges
and C1 charges, the PUT turns off. The next cycle begins
with another positive pulse on the base of Q1 which again
discharges C1.
The input and output frequency can be approximated by
the equation
The PUT provides a simple approach to a voltage
controlled ramp generator, VCRG, as shown in
Figure 6.71(a). The current source formed by Q1 in
conjuction with capacitor C1 set the duration time of the
ramp. As the positive dc voltage at the gate is changed, the
peak point firing voltage of the PUT is changed which
changes the duration time, i.e., increasing the supply
voltage increases the peak point firing voltage causing the
duration time to increase.
Figure 6.71(b) shows a plot of voltage-versus-ramp
duration time for a 0.0047 μF and a 0.01 μF timing
capacitor. The figure indicates that it is possible to have a
change in frequency of 3 ms and 5.4 ms for the 0.0047 μF
and the 0.01 μF capacitor respectively as the control
voltage is varied from 5 to 20 volts.
f in (C1 C2)
f out
C1
For a 10 kHz input frequency with an amplitude of 3 volts,
Table 6.11 shows the values for C1 and C2 needed to divide
by 2 to 11.
This division range can be changed by utilizing the
programmable aspect of the PUT and changing the voltage
on the gate by changing the ratio R6/(R6 + R5). Decreasing
the ratio with a given C1 and C2 decreases the division
range and increasing the ratio increases the division range.
The circuit works very well and is fairly insensitive to
the amplitude, pulse width, rise and fall times of the
incoming pulses.
LOW FREQUENCY DIVIDER
The circuit shown in Figure 6.72 is a frequency divider
with the ratio of capacitors C1 and C2 determining
division. With a positive pulse applied to the base of Q1,
assume that C1 = C2 and that C1 and C2 are discharged.
When Q1 turns off, both C1 and C2 charge to 10 volts each
through R3. On the next pulse to the base of Q1, C1 is again
+ 20 Vdc
Table 6.11
R3
1k
3V
R1
3.9 k
C1
Q2
2N6027
1N4001
8V
R5
5.1 k
D2
Q1
MPS6512
D1
1N4001
OUT
C2
R4
100
R2
2.2 k
R6
5.1 k
C1
C2
Division
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.01 μF
0.02 μF
0.03 μF
0.04 μF
0.05 μF
0.06 μF
0.07 μF
0.08 μF
0.09 μF
0.1 μF
2
3
4
5
6
7
8
9
10
11
Figure 6.72. Low Frequency Divider
V GS V P (1 I O
I DSS )
PUT LONG DURATION TIMER
A long duration timer circuit that can provide a time
delay of up to 20 minutes is shown in Figure 6.73. The
circuit is a standard relaxation oscillator with a FET current
source in which resistor R1 is used to provide reverse bias
on the gate-to-source of the JFET. This turns the JFET off
and increases the charging time of C1. C1 should be a low
leakage capacitor such as a mylar type.
The source resistor of the current source can be
computed using the following equation:
R1 where
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V GS
IO
IO is the current out of the current source.
VP is the pinch off voltage,
VGS is the voltage gate-to-source and,
IDSS is the current, drain-to-source, with the gate
shorted to the source.
For example, the 2N6028 has IP guaranteed to be less than
0.15 μA at RG = 1 M Ohm as shown in Figure 6.73.
The time needed to charge C1 to the peak point firing
voltage of Q2 can be approximated by the following
equation:
+ 20 Vdc
t CDV ,
I
where
Q1
2N5457
t is time in seconds
C is capacitance in μF,
ΔV is the change in voltage across capacitor C1,
and
I is the constant current used to charge C1.
R3
2M
R1
22 M
Q2
2N6028
Maximum time delay of the circuit is limited by the
peak point firing current, lP, needed to fire Q2. For
charging currents below IP, there is not enough current
available from the current source to fire Q2, causing the
circuit to lock up. Thus PUTs are attractive for long
duration timing circuits because of their low peak point
current. This current becomes very small when RG (the
equivalent parallel resistance of R3 and R4) is made large.
C1
10 μF MYLAR
R2
100
OUTPUT
R4
2M
Figure 6.73. 20-Minute, Long Duration Timer
PHASE CONTROL
97% of the power available to the load.
Only one SCR is needed to provide phase control of
both the positive and negative portion of the sine wave
byputting the SCR across the bridge composed of diodes
D1 through D4.
Figure 6.74 shows a circuit using a PUT for phase
control of an SCR. The relaxation oscillator formed by Q2
provides conduction control of Q1 from 1 to 7.8 milliseconds or 21.6° to 168.5°. This constitutes control of over
R1
15 k
2 WATT
D3
D1
115 V rms
60 Hz
D5
1N4114
20 V
C1
0.1 μF
Q1
2N6402
LOAD
100 Ω
D4
D2
R3
1k
R2
250 k
Q2
2N6027
R4
1k
Figure 6.74. SCR Phase Control
BATTERY CHARGER USING A PUT
peak point voltage of the PUT, the PUT fires turning the
SCR on, which in turn applies charging current to the
battery. As the battery charges, the battery voltage
increases slightly which increases the peak point voltage of
the PUT. This means that C1 has to charge to a slightly
higher voltage to fire the PUT. The voltage on C1 increases
until the zener voltage of D1 is reached which clamps the
voltage on C1 and thus prevents the PUT oscillator from
oscillating and charging ceases. The maximum battery
voltage is set by potentiometer R2 which sets the peak
point firing voltage of the PUT.
A short circuit proof battery charger is shown in
Figure 6.75 which will provide an average charging current
of about 8 amperes to a 12 volt lead acid storage battery.
The charger circuit has an additional advantage in that it
will not function nor will it be damaged by improperly
connecting the battery to the circuit.
With 115 volts at the input, the circuit commences to
function when the battery is properly attached. The battery
provides the current to charge the timing capacitor C1 used
in the PUT relaxation oscillator. When C1 charges to the
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series with the SCR).
Resistor R4 is used to prevent the PUT from being
destroyed if R2 were turned all the way up.
Figure 6.75(b) shows a plot of the charging characteristics of the battery charger.
In the circuit shown, the charging voltage can be set from
10 V to 14 V, the lower limit being set by D1 and the upper
limit by T1. Lower charging voltages can be obtained by
reducing the reference voltage (reducing the value of zener
diode D1) and limiting the charging current (using either a
lower voltage transformer, T1, or adding resistance in
T1
14 V
rms
115 V
rms
SCR
A
R1
10 k
R4
1k
2N6027
R2
50 k
+
12 V
PUT
C1
0.1 μF
D1
1N5240
10 V
T2
11Z12
1:1
−
R3
47 k
B
DALE PT50
Figure 6.75. (a). 12-Volt Battery Charger
8
increases which increases the firing point of Q3. This
delays the firing of Q3 because C1 now has to charge to a
higher voltage before the peak-point voltage is reached.
Thus the output voltage is held fairly constant by delaying
the firing of Q5 as the input voltage increases. For a
decrease in the input voltage, the reverse occurs.
Another means of providing compensation for increased
input voltage is achieved by Q2 and the resistive divider
formed by R6 and R7. As input voltage increases, the
voltage at the base of Q2 increases causing Q2 to turn on
harder which decreases the charging rate of C1 and further
delays the firing of Q5.
To prevent the circuit from latching up at the beginning
of each charging cycle, a delay network consisting of Q1
and its associated circuitry is used to prevent the current
source from turning on until the trigger voltage has reached
a sufficiently high level. This is achieved in the following
way: Prior to the conduction of D2, the voltage on the base
of Q1 is set by the voltage divider (R4 + R5)/(R1 + R3 + R4
+ R5). This causes the base of Q1 to be more positive than
the emitter and thus prevents Q1 from conducting until the
voltage across R3 is sufficient to forward bias the
base-emitter junction of Q1. This occurs when the line
voltage has increased to about 15 volts.
The circuit can be operated over a different voltage range
by changing resistors R6 and/or R4 which change the
charging rate of C1.
SPECIFIC GRAVITY OF ELECTROLYTE versus TIME
7
6
1200
5
4
CHARGING CURRENT versus TIME
1150
0
1
2
3
4
5
TIME (HR)
6
7
8
CURRENT (AMPS)
SPECIFIC GRAVITY
1250
3
9
2
Figure 6.75 (b) Charging Characteristics
of Battery Charger
90 V rms VOLTAGE REGULATOR USING A PUT
The circuit of Figure 6.76 is an open loop rms voltage
regulator that will provide 500 watts of power at 90 V
rms with good regulation for an input voltage range of
110 − 130 V rms.
With the input voltage applied, capacitor C1 charges
until the firing point of Q3 is reached causing it to fire. This
turns Q5 on which allows current to flow through the load.
As the input voltage increases, the voltage across R10
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135
Figure 6.76(b) provides a plot of output voltage and
conduction angle versus input voltage for the regulator. As
LOAD
500 W
90 V ± 2
the figure indicates, good regulation can be obtained
between the input voltage range of 110 to 130 volts.
R1
10 k
R9
100 k
R6
300 k
R2
1k
R3
110-130 V
rms
1k
R4
10 k
D2
1N4747
20 V
Q3
2N6027
Q1
2N3906
D1
R5
6.8 k
Q5
MCR16M
Q2
2N3903
C1
0.1 μF
100 V
R7
4.7 k
R8
10 k
R10
6.8 k
100
7
90
6
80
5
70
4
CONDUCTION TIME
OUTPUT VOLTAGE
60
50
80
90
100
110 120 130 140 150
INPUT VOLTAGE (V rms)
3
160
this time the voltage on C3 lags the line voltage. When the
line voltage goes through zero there is still some charge on
C3 so that when the line voltage starts negative C3 is still
discharging into the gate of Q2. Thus Q2 is also turned on
near zero on the negative half cycle. This operation
continues for each cycle until switch S1 is closed, at which
time SCR Q1 is turned on. Q1 shunts the gate current away
from Q2 during each positive half cycle keeping Q2 from
turning on. Q2 cannot turn on during the negative cycle
because C3 cannot charge unless Q2 is on during the
positive half cycle.
If S1 is initially closed during a positive half cycle, SCR
Q1 turns on but circuit operation continues for the rest of
the complete cycle and then turns off. If S1 is closed during
a negative half cycle, Q1 does not turn on because it is
reverse biased. Q1 then turns on at the beginning of the
positive half cycle and Q2 turns off.
Zero-point switching when S1 is opened is ensured by
the characteristic of SCR Q1. If S1 is opened during the
positive half cycle, Q1 continues to conduct for the entire
half cycle and TRIAC Q2 cannot turn on in the middle of
the positive half cycle. Q2 does not turn on during the
negative half cycle because C3 was unable to charge
during the positive half cycle. Q2 starts to conduct at the
first complete positive half cycle. If S1 is opened during
the negative half cycle, Q2 again cannot turn on until the
beginning of the positive half cycle because C3 is
uncharged.
A 3-volt gate signal for SCR Q1 is obtained from D1,
R1, C1, and D6.
CONDUCTION ANGLE (ms)
OUTPUT VOLTAGE (V rms)
Figure 6.76. (a). rms Voltage Regulator
2
170
(b). Output Voltage and Conduction Angle
versus Input Voltage
TRIAC ZERO-POINT SWITCH APPLICATIONS
BASIC TRIAC ZERO-POINT SWITCH
Figure 6.77 shows a manually controlled zero-point
switch useful in power control for resistive loads. Operation of the circuit is as follows. On the initial part of the
positive half cycle, the voltage is changing rapidly from
zero causing a large current flow into capacitor C2. The
current through C2 flows through R4, D3, and D4 into the
gate of the TRIAC Q2 causing it to turn on very close to
zero voltage. Once Q2 turns on, capacitor C3 charges to the
peak of the line voltage through D5. When the line voltage
passes through the peak, D5 becomes reverse-biased and
C3 begins to discharge through D4 and the gate of Q2. At
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R3
1.2 k
7W
D1
1N4003
C2
2 μF
200 V
R4
150 Ω
1W
R1
12 k
2W
115 VAC
60 Hz
+
Q2
2N6346
D3
1N4003
D4
1N4001
D5
1N4003
D2
1N4003
Q1
MCR1906-4
R2
10 k
C1
10 μF
5V
+
S1
D6
1N4372
+
R5
1k
2W
C3
1 μF
200 V
LOAD
Figure 6.77. Zero-Point Switch
AN INTEGRATED CIRCUIT ZERO VOLTAGE SWITCH
zero voltage point of the ac cycle. This eliminates the RFI
resulting from the control of resistive loads like heaters and
flashing lamps. Table 6.12 specifies the value of the input
series resistor for the operating line voltage. Figure 6.79
shows the pin connection for a typical application.
A single CA3059/79 integrated circuit operating directly
off the ac line provides the same function as the discrete
circuit shown in Figure 6.77. Figure 6.78 shows its block
diagram. The circuit operates a power triac in quadrants
one and four, providing gate pulses synchronized to the
2
RS
5
VCC
POWER
SUPPLY
LIMITER
AC
INPUT
VCC
CURRENT
BOOST
ZERO
CROSSING
DETECTOR
12
RL
3
MT2
DC MODE or
400 Hz INPUT
14
RP
100
μF +
AC
INPUT 15 V −
VOLTAGE
13
9
*
RX
TRIAC
DRIVE
PROTECTION
CIRCUIT
+
ON/OFF
SENSING
AMP
−
VCC
10
11
8
*NTC SENSOR
GND
1
INHIBIT
7
Figure 6.78. Functional Block Diagram
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6
EXTERNAL TRIGGER
4
GATE
MT1
Table 6.12.
9 10 11
RL
3
AC Input Voltage
(50/60 Hz)
vac
Input Series
Resistor (RS)
kΩ
Dissipation
Rating for RS
W
24
120
208/230
277
2.0
10
20
25
0.5
2.0
4.0
5.0
RS
10 k
T2800D
5
120 Vrms
60 Hz
CA3059
4
7
TEMPERATURE CONTROL WITH ZERO-POINT
SWITCHING
8 13 14 2
R2
5k
ON
OFF
ZERO VOLTAGE SWITCH PROPORTIONAL BAND
TEMPERATURE CONTROLLER
Figure 6.80 shows the block diagram for the UAA1016B
integrated circuit temperature controller. Figure 6.81 shows
a typical application circuit. This device drives triacs with a
zero voltage full wave technique allowing RFI free power
regulation of resistive loads and adjustable burst frequency
to comply with standards. It operates directly off the ac line
triggers the triac in Q2 and Q3, is sensor fail-safe, and
provides proportional temperature control over an adjustable band. Consult the device data sheet (DS9641) for
detailed information.
R1
5k
+
100 μf
15 V
Figure 6.79. Zero Voltage Switch Using CA3059
Integrated Circuit
220 VAC
TEMP.
SET
R1
FAIL-SAFE
R2
3
4
VREF
PULSE
AMPLIFIER
+
SAMPLING
FULL WAVE
LOGIC
−
COMPARATOR
R4
1.0
M
UAA1016B
6
MAC224-8
SAWTOOTH
GENERATOR
7
1
SYNCHRONIZATION
POWER
SUPPLY
(NTC)
TEMP.
SENSOR
LOAD
2
R3
RL
180 k
8
CPin 2
− VCC
5
+
RSYNC
Design Notes:
1. Let R4 5RL
220 VAC
2. Select R2 Ratio for a symmetrical reference deviation centered about Pin 1 output swing, R2 will be slightly greater than R3.
R3
DV Pin1
3. Select R2 and R3 values for the desired reference deviation where DV REF R4 1
R2 | | R3
Figure 6.80. UA1016B Block Diagram and Pin Assignment
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138
50 k
6.8 k
22 k
0.1
μF
6
3
UAA1016B
MAC224-8
R4
1
RT
6.8
k
MOV
4
100
Ω
220 VAC
7
RL
47 μF
8.0 V
+
2
8
5
+
100 k
100 μF
HEATER
2.0 kW
18 k
RT : NTC R @ 25°C = 22 k 10%
B = 3700
2.0 W
1N4005
MOV: 250 VAC VARISTOR
Figure 6.81. Application Circuit — Electric Radiator with Proportional Band
Thermostat, Proportional Band 1°C at 25°C
TRIAC RELAY-CONTACT PROTECTION
the TRIAC on after switch S1 has been opened. The time
constant of R1 plus R2 and C1 is set so that sufficient gate
current is present at the time of relay drop-out after the
opening of S1, to assure that the TRIAC will still be on. For
the relay used, this time is 15 ms. The TRIAC therefore
limits the maximum voltage, across the relay contacts upon
dropout to the TRIAC’s voltage drop of about 1 volt. The
TRIAC will conduct until its gate current falls below the
threshold level, after which it will turn off when the anode
current goes to zero. The TRIAC will conduct for several
cycles after the relay contacts open.
This circuit not only reduces contact bounce and arcing
but also reduces the physical size of the relay. Since the
relay is not required to interrupt the load current, its rating
can be based on two factors: the first is the rms rating of the
current-carrying metal, and the second is the contact area.
This means that many well-designed 5 ampere relays can
be used in a 50 ampere load circuit. Because the size of the
relay has been reduced, so will the noise on closing.
Another advantage of this circuit is that the life of the relay
will be increased since it will not be subjected to contact
burning, welding, etc.
The RC circuit shown across the contact and TRIAC (R3
and C2) is to reduce dv/dt if any other switching element is
used in the line.
A common problem in contact switching high current
is arcing which causes erosion of the contacts. A
solution to this problem is illustrated in Figure 6.82.
This circuit can be used to prevent relay contact arcing
for loads up to 50 amperes.
There is some delay between the time a relay coil is
energized and the time the contacts close. There is also a
delay between the time the coil is de-energized and the time
the contacts open. For the relay used in this circuit both
times are about 15 ms. The TRIAC across the relay
contacts will turn on as soon as sufficient gate current is
present to fire it. This occurs after switch S1 is closed but
before the relay contacts close. When the contacts close,
the load current passes through them, rather than through
the TRIAC, even though the TRIAC is receiving gate
current. If S1 should be closed during the negative half
cycle of the ac line, the TRIAC will not turn on
immediately but will wait until the voltage begins to go
positive, at which time diode D1 conducts providing gate
current through R1. The maximum time that could elapse
before the TRIAC turns on is 8-1/3 ms for the 60 Hz
supply. This is adequate to ensure that the TRIAC will be
on before the relay contact closes. During the positive half
cycle, capacitor C1 is charged through D1 and R2. This
stores energy in the capacitor so that it can be used to keep
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AN AUTOMATIC AC LINE VOLTAGE SELECTOR
USING THE MC34161 AND A TRIAC
R3
C2
0.1 μF
47
50 AMP
LOAD
Line operated switching regulators run off of 120 or 240
VAC by configuring the main reservoir input capacitor
filter as a full-wave doubler or full-wave bridge. This
integrated circuit provides the control signals and triggering for a TRIAC to automatically provide this function.
Channel 1 senses the negative half cycles of the AC line
voltage. If the line voltage is less than 150 V, the circuit
will switch from bridge mode to voltage doubling mode
after a preset time delay. The delay is controlled by the
100 kΩ resistor and the 10 μF capacitor. If the line voltage
is greater than 150 V, the circuit will immediately return to
fullwave bridge mode.
MAC210A8
S1
115 VAC
60 Hz
R1
1.5 k
10 W
115 V RELAY WITH PICKUP AND DROP-OUT TIMES
OF 10-20 ms
R2
10
10 W
C1
20 μF
250 V
D1 1N4004
+
Figure 6.82. TRIAC Prevents Relay Contact Arcing
B+
220
250 V
75 k
+
220
250 V
75 k
MR506
T
INPUT
92 TO 276
VAC
MAC +
228A6FP
8
3.0 A
2.54 V
REFERENCE
1
10 k
7
+
2 +
100 k
2.8 V
1.27 V
−
+
+
1N
4742
+
10
+
0.6 V
+
−
1.27 V
47
4
10 k
3W
Figure 6.83. Automatic AC Line Voltage Selector
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1.2 k
−
+
+
−
+
1.6 M
3
10 k
6
5
RTN
AN1045/D
Series Triacs
In AC High Voltage
Switching Circuits
http://onsemi.com
By George Templeton
Thyristor Applications Engineer
APPLICATION NOTE
INTRODUCTION
Edited and Updated
This paper describes the series connection of triacs to
create a high voltage switch suitable for operation at voltages up to 2000 Volts. They can replace electromechanical
contactors or extend their current rating and lifetime. Motor
starters and controllers operating at line voltages of 240
Volts or more require high-voltage switches. Transformer
action and resonant snubber charging result in voltages
much greater than the peak of the line. Triacs can be subjected to both commutating and static dV/dt when multiple
switching devices are present in the circuit. Snubber
designs to prevent static dV/dt turn-on result in higher voltages at turn-off. Variable load impedances also raise voltage requirements.
The benefits of series operation include: higher blocking
voltage, reduced leakage, better thermal stability, higher
dV/dt capability, reduced snubber costs, possible snubberless operation, and greater latitude in snubber design. The
advantages of triacs as replacements for relays include:
winding, and start capacitor voltage. This voltage increases
when triac turn-off occurs at higher rpm.
• Small size and light weight
• Safety — freedom from arcing and spark initiated
explosions
• Long lifespan — contact bounce and burning eliminated
• Fast operation — turn-on in microseconds and turn-off
in milliseconds
• Quiet operation
The triacs retrigger every half cycle as soon as the line
voltage rises to the value necessary to force the trigger current. The instantaneous line voltage V is
TRIGGERING
Figure 1 illustrates a series thyristor switching circuit. In
this circuit, the top triac triggers in Quadrant 1 when the
bottom triac triggers in Quadrant 3. When the optocoupler
turns on, gate current flows until the triacs latch. At that
time, the voltage between the gate terminals drops to about
0.6 Volts stopping the gate current. This process repeats
each half cycle. The power rating of the gate resistor can be
small because of the short duration of the gate current.
Optocoupler surge or triac gate ratings determine the minimum resistance value. For example, when the maximum
optocoupler ITSM rating is 1 A:
R g V peak
I max
R g 750 V
1 A 750 Ohm
V I GT R g 2 V GT 2 V TM
August, 1999 − Rev. 2
(1.1)
where VGT, IGT are data book specifications for the triac and
VTM is the on-voltage specification for the optocoupler.
The phase delay angle is
Triacs can be used to replace the centrifugal switch in
capacitor start motors. The blocking voltage required of the
triac can be much greater than the line voltage would suggest. It must block the vector sum of the line, auxiliary
© Semiconductor Components Industries, LLC, 1999
(1.0)
q d SIN 1
141
V
2 V
LINE
(1.2)
Publication Order Number:
AN1045/D
AN1045/D
IL
IG
G
MEAN
MT1
RG
DESIGN
CAPABILITY
ΔI
MT2
6σ
6σ
3σ
3σ
MT2
PROCESS WIDTH
MT1
G
Figure 6.1. Series Switch
Figure 6.2. Designing for Probable Leakage
STATIC VOLTAGE SHARING
Maximum blocking voltage capability results when the
triacs share voltage equally. The blocking voltage can be dc
or ac. A combination of both results when the triac switches
the start winding in capacitor start motors. In the simple
series connection, both triacs operate with an identical leakage current which is less than that of either part operated
alone at the same voltage. The voltages across the devices
are the same only when their leakage resistances are identical. Dividing the voltage by the leakage current gives the
leakage resistance. It can range from 200 kohm to 2000
megohm depending on device characteristics, temperature,
and applied voltage.
Drawing a line corresponding to the measured series
leakage on each device’s characteristic curve locates its
operating point. Figure 3a shows the highest and lowest
leakage units from a sample of 100 units. At room temperature, a leakage of 350 nA results at 920 Volts. The lowest
leakage unit blocks at the maximum specified value of 600
Volts, while the highest blocks 320 Volts. A 50 percent
boost results.
Figure 3b shows the same two triacs at rated TJmax. The
magnitude of their leakage increased by a factor of about
1000. Matching between the devices improved, allowing
operation to 1100 Volts without exceeding the 600 Volt rating of either device.
Identical case temperatures are necessary to achieve
good matching. Mounting the devices closely together on a
common heatsink helps.
A stable blocking condition for operation of a single triac
with no other components on the heatsink results when
turn leads to greater leakage. If the rate of heat release at the
junction exceeds the rate of removal as temperature
increases, this process repeats until the leakage current is
sufficient to trigger the thyristor on.
DC blocking simplifies analysis. A design providing
stable dc operation guarantees ac performance. AC operation allows smaller heatsinks.
The last term in the stability equation is the applied voltage when the load resistance is low and the leakage causes
negligible voltage drop across it. The second term is the
thermal resistance from junction to ambient. The first term
describes the behavior of leakage at the operating conditions. For example, if leakage doubles every 10°C, a triac
operating with 2 mA of leakage at 800 Vdc with a 6°C/W
thermal resistance is stable because
dI MT
dT J
dT
dP J
dPJ dI
J
MT
1
2 mA
10°C
800 V
6°C
W 0.96
Operating two triacs in series improves thermal stability.
When two devices have matched leakages, each device sees
half the voltage and current or 1/4 of the power in a single
triac. The total leakage dissipation will approach half that
of a single device operated at the same voltage. The additional voltage margin resulting from the higher total blocking voltage reduces the chance that either device will operate near its breakdown voltage where the leakage current
increases rapidly with small increments in voltage. Higher
voltage devices have lower leakage currents when operated
near breakdown. Consequently, the highest breakover voltage unit in the pair will carry the greatest proportion of the
burden. If the leakage current is large enough to cause significant changes in junction temperature, (ΔTJ = φJC PD),
the effect will tend to balance the voltage division between
the two by lowering the leakage resistance of the hotter
unit. If the leakage mismatch between the two is large,
nearly all the voltage will drop across one device. As a
result there will be little benefit connecting two in series.
Series blocking voltage depends on leakage matching.
Blocking stability depends on predictable changes in leakage with temperature. Leakage has three components.
(2.0)
Thermal run-away is a regenerative process which occurs
whenever the loop gain in the thermal feedback circuit
reaches unity. An increase in junction temperature causes
increased leakage current and higher power dissipation.
Higher power causes higher junction temperature which in
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AN1045/D
HIGH
LOW
ΔIL
LOW
HIGH
(a)
100 V/
100 nA/
(b)
25°C
100 μA/
100 V/
125°C
Figure 6.3. Leakage Matching versus Temperature
Surface Leakage
from 70 to 150°C. Actual values measured 0.064 at 125°
and 0.057 at 150°.
Deviations from this behavior will result at voltages and
temperatures where leakage magnitude, current gain, and
avalanche multiplication aid unwanted turn-on. Sensitive
gate triacs are not recommended for this reason.
Passivation technique, junction design, and cleanliness
determine the size of this component. It tends to be small
and not very dependent on temperature.
Diffusion Leakage
Measurements with 1 volt reverse bias show that this
component is less than 10 percent of the total leakage for
allowed junction temperatures. It follows an equation of the
form:
I e (qv
kT)
DERATING AND LEAKAGE MATCHING
Operation near breakdown increases leakage mismatch
because of the effects of avalanche multiplication. For
series operation, devices should be operated at least 100
Volts below their rating.
(2.1)
and doubles about every 10°C. Its value can be estimated
by extrapolating backward from high temperature data
points.
20
18
PERCENT (SAMPLE SIZE = 100)
Depletion Layer Charge Generation
This component is a result of carriers liberated from
within the blocking junction depletion layer. It grows with
the square root of the applied voltage. The slope of the leakage versus applied voltage is the mechanism allowing for
series operation with less than perfect leakage matching.
Predictable diffusion processes determine this leakage. At
temperatures between 70 and 150°C it is given by:
i e E
kT
(2.2)
650 V
16
550 V
14
TJ = 25°C
12
10
8
6
4
2
where E = 1.1 eV, k = 8.62E − 5 eV/k, T = degrees Kelvin,
and k = 8.62 x 10 −5 eV/k.
It is useful to calculate the percentage change in leakage
current with temperature:
0.6
0.7
0.8
0.9
1
1.1
1.2
1.3
1.4
1.5
1.6
Figure 6.4. Normalized Leakage (Mean = 1.0)
A 1 di E 0.08 8%
i dT J
°C
kT 2
Figure 4 shows the leakage histogram for a triac sample
operated at two different voltages. The skewedness in the
high-voltage distribution is a consequence of some of the
sample operating near breakdown.
The coefficient A was evaluated on 3 different die size
triacs by curve fitting to leakage measurements every 10°
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HEATSINK SELECTION
Low duty cycles allow the reduction of the heatsink size.
The thermal capacitance of the heatsink keeps the junction
temperature within specification. The package time
constant (Cpkg RθJA) is long in comparison with the thermal
response time of the die, causing the instantaneous TJ to
rise above the case as it would were the semiconductor
mounted on an infinite heatsink. Heatsink design requires
estimation of the peak case temperature and the use of the
thermal derating curves on the data sheet. The simplest
model applies to a very small heatsink which could be the
semicondutor package itself. When θSA is large in comparison with θCHS, it is sufficient to lump both the package and
heatsink capacitances together and treat them as a single
quantity. The models provide good results when the heatsink is small and the thermal paths are short.
Model C, Figure 5 is a useful simplification for low duty
cycle applications. Increasing heatsink mass adds thermal
capacitance and reduces peak junction temperature. Heatsink thermal resistance is proportional to surface area and
determines the average temperature.
Solving equations (2.0) and (2.3) for the thermal resistance required to prevent runaway gives:
θ JA 1
A V i
(3.0)
where θJA is thermal resistance, junction to ambient, in
°C/W, A = 0.08 at TJ = 125°C, V = rated VDRM, and i =
rated IDRM.
θJA must be low enough to remove the heat resulting
from conduction losses and insure blocking stability. The
latter can be the limiting factor when circuit voltages are
high. For example, consider a triac operated at 8 amps
(rms) and 8 Watts. The allowed case temperature rise at 25°
ambient is 85°C giving a required θCA (thermal resistance,
case to ambient) of 10.6°C/W. Allowing 1°C/W for θCHS
(thermal resistance, case to heatsink) leaves 9.6°C/W for
θSA (thermal resistance, heatsink to ambient). However,
thermal stability at 600 V and 2 mA IDRM requires θJA =
10.4°C/W. A heatsink with θSA less than 7.4°C/W is
needed, given a junction to case thermal resistance of
2°C/W.
The operation of devices in series does not change the
coefficient A. When matching and thermal tracking is perfect, both devices block half the voltage. The leakage current and power divide by half and the allowed θJA for
blocking stability increases by 4.
q SA 32.6 A (0.47)
(3.1)
where A = total surface area in square inches, θSA = thermal
resistance sink to ambient in °C/W.
Analysis of heatsink thermal response to a train of periodic pulses can be treated using the methods in
ON Semiconductor application note AN569 and Figure 6.
For example:
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AN1045/D
θCA
Pd
CPKG
Pd θCA
θCA
ton
CPKG
TC
TC
TA
TA
(a.) Standard Thermal Analogue For a Thyristor
in Free Air
(b.) Equivalent Circuit For
(a)
In Circuit (B):
The steady state case temperature is given by
(5.0)
T CSS P d q CA T A in °C
where Pd = Applied average power, watts
θCA = Case to ambient thermal resistance, °C/W
TA = ambient temperature, °C
The package rises toward the steady state temperature exponentially with time constant
(5.1)
t q CA C PKG, seconds
In terms of measurable temperatures:
DT C
pk
(5.3)
r(t on) DT CSS
In model (b.) this is
r(t on) (1 e
(5.4)
Solving 5-4 for the package capacitance gives
C PKG (5.5)
where Cpkg = HM, Joules/°C
H = Specific heat, calories/(gm S °C)
M = Mass in grams
and 1 Calorie = 4.184 Joule
1 Joule = 1 Watt S Sec
ton
t
)
t on
(θ CA In (1 r(t on))
Use simplified model C when
t on t
DT C DT CSS
pk
The case temperature rise above ambient at the end of
power pulse is:
(5.2)
where DT C
DT C
pk
DT CSS(1 e ton
t)
CPKG
Pd
TC TA
pk
pk
DT CSS T CSS T A
To account for thermal capacity, a time dependent factor r(t) is
applied to the steady state case-to-ambient thermal resistance. The package thermal resistance, at a given on-time,
is called transient thermal resistance and is given by:
R qCA (t on) r(t on) q CA
TA
(c.) Simplified Model
(5.6) T C where r(ton) = Unitless transient thermal impedance
coefficient.
P d t on
C PKG
TA
Figure 6.5. Transient Thermal Response For a Single Power Pulse
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TC
AN1045/D
R (T p) (1 e 180
150) .6988
Assume the case temperature changes by 40°C for a
single power pulse of 66.67 W and 3 s duration. Then from
equation (5.6):
C pkg R (t on Tp) (1 1 183
150) .7047
(66.7 Watts) (3 seconds)
5 Joules
40°C
°C
Then from Figure 6:
delta TC = (1.111 + 46.225 + 1.333 − 46.61) 30 = 61.8°C
If the ambient temperature is 25°C, TC = 87°C.
The heatsink thermal resistance can be determined by
applying dc power, measuring the final case temperature,
and using equation (5.0).
TC TA
PD
COMPENSATING FOR MAXIMUM
SPECIFIED LEAKAGE
175-25 30°C
W
5
Identical value parallel resistors around each triac will
prevent breakdown resulting from mismatched leakages.
Figure 7 derives the method for selecting the maximum
allowed resistor size. A worst case design assumes that the
series pair will operate at maximum TJ and that one of the
triacs leaks at the full specified value while the other has no
leakage at all. A conservative design results when the tolerances in the shunt resistors place the highest possible resistor across the low leakage unit and the lowest possible
resistor around the high leakage unit.
This method does not necessarily provide equal voltage
balancing. It prevents triac breakover. Perfect voltage sharing requires expensive high-wattage resistors to provide
large bleeder currents.
The application requires a 3 s on-time and 180 s period at
66.7 W. Then
P avg (66.7 W) (3
180) 1.111 W
Nth
PULSE
N+1
PULSE
Pd
ton
tp
PAVG
0
IDRM (T2)
DT C (N 1) [P AVG (P d P AVG) r (t on t p) P d r (t on)
I2
T2
R2
P d r (t p)]q CA
ΔIL
Where Δ TC (N + 1) = maximum rise above ambient
Pd = applied average power within a pulse
PAV G = average power within a period
r(ton + tp) = time dependent factor for sum of ton
and tp
r(ton) = time dependent factor for ton
r(tp) = time dependent factor for tp
VS
IDRM (T1)
I1
R1
V1
T1
V1 V SR 1
R1 R2
DI LR 1R 2
R1 R2
Let R1 = R (1 + p) and R2 = R (1 −p) where
R = Nominal resistor value
p = 0.05 for 5% tolerance, etc.
Figure 6.6. Steady State Peak Case Temperature Rise
Using equation (5.3), the theoretical steady state case
temperature rise is:
R
2 V DRM V S (1 p)
DI L (1 p 2)
Worst case becomes:
T CSS T A (66.7 W) (30°C
W) 2000°C
and
and
R(t on) R (3 s) (40°C measured rise)
2000 0.02
IDRM (T1 ) = 0; IDRM (T2 ) = Spec. max. value
ΔIL = Spec. Max. Value
Figure 6.7. Maximum Allowed Resistor for Static
Voltage Sharing
From equation (5.4) and (5.1):
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COMPENSATION FOR PROBABLE LEAKAGE
Theoretically there would be no more than 3.4 triacs per
million exceeding the design tolerance even if the mean
value of the leakage shifted by plus or minus 1.5 sigma.
Real triacs have a leakage current greater than zero and less
than the specified value. Knowledge of the leakage distribution can be used to reduce resistor power requirements. The
first step is to statistically characterize the product at maximum temperature. Careful control of the temperature is critical because leakage depends strongly on it.
The process width is the leakage span at plus or minus 3
standard deviations (sigma) from the mean. To minimize
the probability of out of spec parts, use a design capability
index (Cp) of 2.0.
C p (design DI)
(process width)
SELECTING RESISTORS
Small resistors have low voltage ratings which can
impose a lower constraint on maximum voltage than the
triac. A common voltage rating for carbon resistors is:
Rated Power (W)
1/4 Watt
1/2
1
2
(4.0)
Cp (12 sigma)
(6 sigma)
Figure 2 and Figure 7 describe this. Substituting delta IL
at 6 sigma in Figure 7 gives the resistor value. The required
power drops by about 4.
Maximum Voltage (V)
250 Volts
350
500
750
Series resistors are used for higher voltage.
ACTUAL TRIAC
I
Rmin
Let V DRM E
IDRM
MODEL
TRIAC
E V DRM
E
Rmax
R max R max
R max R min
V DRM
VMT2 − 1
I min
1 I min
I max
R min V DRM
I max
(8.0)
VDRM
(a) Equivalent Circuit
(b) Model
Figure 6.8. Maximum Voltage Sharing Without Shunt Resistor
OPERATION WITHOUT RESISTORS
Table 1. Normalized leakage and voltage boost factor.
(Mean = 1.0)
Figure 8 derives the method for calculating maximum
operating voltage. The voltage boost depends on the values
of Imin and Imax. For example :
Voltage (V)
550
650
550
550
550
550
550
TJ (°C)
25
25
100
125
125
150
150
510K
Rshunt
131 mA
1 1.19
683 mA
A 19 percent voltage boost is possible with the 6 sigma
design. Testing to the measured maximum and minimum of
the sample allows the boost to approach the values given in
Table 1.
(1 0.835
1.228) 1.68
—
—
—
—
1.5M
1.5M
Sample Size
100
100
16
16
16
16
16
Maximum
1.31
5
1.59
1
1.18
7
1.22
8
1.12
3
1.34
6
1.18
6
Minimum
0.72
9
0.68
1
0.84
0
0.83
5
0.92
0
0.82
0
0.87
7
Sigma
0.116
0.17
2
0.10
6
0.113
0.05
5
0.13
2
0.08
4
Sample Boost
1.55
1.43
1.71
1.68
1.82
1.61
1.74
6 Sigma Boost
1.18
1.00
1.22
1.19
1.50
1.12
1.33
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AN1045/D
COMPENSATING FOR SURFACE LEAKAGE
Triacs can tolerate very high rates of voltage rise when
the peak voltage magnitude is below the threshold needed
to trigger the device on. This behavior is a consequence of
the voltage divider action between the device collector and
gate-cathode junction capacitances. If the rise-time is made
short in comparison with minority carrier lifetime, voltage
and displaced charge determine whether the device triggers
on or not. Series operation will extend the range of voltage
A small low power shunt resistance will provide nearly perfect low temperature voltage sharing and will improve high
temperature performance. It defines the minimum leakage
current of the parallel triac-resistor combination. The design
method in Figure 8 can be used by adding the resistor current
to the measured maximum and minimum leakage currents of
the triac sample. This is described in Table 1.
and load conditions where a static dV snubber is not
dt
SERIES dV
dt s
dV
dt
The series connection will provide twice the
needed.
Figure 10 graphs the results of measurements on two
series connected triacs operated without snubbers. The
series connection doubled the allowed step voltage. However, this voltage remained far below the combined 1200 V
breakover voltage of the pair.
s
capability of the lowest device in the pair (Figure 9).
Dynamic matching without a snubber network depends
on equality of the thyristor self capacitance. There is little
variation in junction capacitance. Device gain variations
introduce most of the spread in triac performance.
The blocking junction capacitance of a thyristor is a
declining function of dc bias voltage. Mismatch in static
blocking voltage will contribute to unequal capacitances.
However, this effect is small at voltages beyond a few volts.
The attachment of a heatsink at the high-impedance node
formed by connection of the triac main-terminals can also
contribute to imbalance by introducing stray capacitance to
ground. This can be made insignificant by adding small
capacitors in parallel with the triacs. Snubbers will serve
the same purpose.
MAXIMUM STEP VOLTAGE (V)
800
700
600
500
400
V
300
dV 10kV
ms
dt
f = 10 Hz
pw = 100 μs
200
100
0
0
10,000
9
8
7
6
5
4
40
60
80
TJ (°C)
100
120
140
160
Figure 6.10. Step Blocking Voltage VS
TJ (Unsnubbed Series Triacs)
dt tests performed at 1000 V and less
Exponential dV
1
3
EXPONENTIAL STATIC dv/dtS (V/ μs)
20
2
R
occur because of breakdown or dV . The former was the
C
dt
limiting factor at junction temperatures below 100°C. Performance improved with temperature because device gain
aided voltage sharing. The triac with the highest current
gain in the pair is most likely to turn-on. However, this
device has the largest effective capacitance. Consequently
2
1000
9
8
7
6
5
4
R
C
1
it is exposed to less voltage and dV . At higher temperadt
R = 270 kΩ
C = 1000 pF
Vpk = 1000 V
3
s
than 2 kV/μs showed that turn-on of the series pair can
tures, rate effects dominated over voltage magnitudes, and
the capability of the series pair fell. dV performance of the
dt
2
series devices was always better than that of a single triac
alone.
100
0
15
30
45
60
75
90
TURNOFF
105 120 135 150
JUNCTION TEMPERATURE (TJ) °C
Process tolerances cause small variations in triac turn-off
time. Series operation will allow most of the reapplied
blocking voltage to appear across the faster triac when a
dynamic voltage sharing network is not used.
Figure 6.9. Exponential Static dV/dt, Series
MAC15-8 Triacs
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AN1045/D
The triacs were mounted on a temperature controlled
hotplate. The single pulse non-repetitive test aids junction
temperature control and allows the use of lower power
rated components in the snubber and load circuit.
CL
15K
G2
13K
S1
2W
15K
2W
11
Ω
2W
+
100 V
MOC3081
MT1
G2
MT2 T2
G2
2.2 Meg
910
1/2W
S1
+
20 μF
200 V
270K
2W
MT2
1N4001
G1
PUSH TO
TEST
2.2 Meg
MOC3081
−
MT1, T2
510
910
S4A
PEARSON 301X
1−PROBE
S4B
G1
G1
T1
MT1
270K
2W
CL
Rs
LL
Cs
S2
Hg
RELAY
Cs
TRIAD C30X 50H, 3500 Ω
Figure 11 describes the circuit used to investigate this
behavior. It is a capacitor discharge circuit with the load
series resonant at 60 Hz. This method of testing is desirable
because of the reduced burn and shock hazard resulting
from the limited energy storage in the load capacitor.
S3
Rs
CL
VCC
1.5 kV
510
MT1, T1
(a) Triac Gate
Circuit
S1 = GORDES MR988 REED WOUND
WITH 1 LAYER AWG #18
LL = 320 MHY
CL = 24 μFD, NON-POLAR
(c) Load Circuit
REVERSE S4 AND VCC TO
CHECK OPPOSITE POLARITY.
(b) Optocoupler Gate Circuit
Figure 6.11.
dV
Test Circuit
dt c
suggest that the reverse recovery charge is less than 2
micro-coulombs. Recovery currents cannot be much
greater than IH or IGT, or the triac would never turn-off.
Recovery can be forward, reverse, or near zero current
depending on conditions.
Snubber design for the series switch has the following
objectives:
Snubberless turn-off at 1200 V and 320 milli-henry
resulted in 800 V peak and 100 V/μs. Although this test
exceeded the ratings of the triacs, they turned off successfully.
Snubberless operation is allowable when:
1. The total transient voltage across both triacs does not
exceed the rating for a single device. This voltage
depends on the load phase angle, self capacitance of
the load and triac, damping constant, and natural resonance of the circuit.
dt 2. The total dV
c
• Controlling the voltage peak. Resonant charging will
magnify the turn-off voltage.
• Controlling the voltage rate. Peak voltage trades with
voltage rate.
• Equalizing the voltage across the series devices by
providing for imbalance in turn-off charge.
Designs that satisfy the first two objectives will usually
provide capacitor values above the minimum size. Select
the snubber for a satisfactory compromise between voltage
across the series combination does
not exceed the capability of a single device.
Maximum turn-off voltage capability and tolerance for
variable loads requires the use of a snubber network to provide equal dynamic voltage sharing. Figure 12 and
Figure 13 derives the minimum size snubber capacitor
allowed. It is determined by the recovery charge of the
triac. Measurements in fast current crossing applications
and dV . Then check the capacitor to insure that it is suffidt
ciently large.
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AN1045/D
dl CAPABILITY
dt
VMT2-1
AND
IMT2
C2
T2
Q+ Δ
Q
ΔQ
VS
T1
Q
The hazard of thyristor damage by dl overstress is
dIdtc
V2
Q2
dt
greater when circuit operating voltages are high because dl
φ
C1 Q
1
ΔQ
IRRM
VDRM
dt
t
is proportional to voltage. Damage by short duration transients is possible even though the pulse is undetectable
when observed with non-storage oscilloscopes. This type
of damage can be consequence of snubber design, transients, or parasitic capacitances.
A thyristor can be triggered on by gate current, exceeding
(dv/dt)c
VMT
2-1
Worst case:
C 2 C(1 p); C 1 C(1 p); Q 1 0; Q 2 DQ
where C = Nominal value of capacitor
and p = 0.1 for 10% tolerance, etc.
ΔQ = Reverse recovery charge
dt its breakdown voltage, or by exceeding its dV
age can still occur if the rate of follow on dl is high. Repetidt
For the model shown above,
C
Q1
C1
Q2
C2
capabili-
ty. In the latter case, a trigger current is generated by charging of the internal depletion layer capacitance in the device.
This effect aids turn-on current spreading, although dam-
Note that T1 has no charge while T2 carries full
recovery charge.
VS s
tive operation off the ac line at voltages above breakdown is
a worst case condition. Quadrant 3 has a slightly slower
gated turn-on time, increasing the chance of damage in this
direction. Higher operating voltages raise power density
and local heating, increasing the possibility of die damage
due to hot-spots and thermal run-away.
Q1
Q 1 DQ
C(1 p)
C(1 p)
DQ
2 V DRM V S(1 p)
Figure 6.12. Minimum Capacitor Size for Dynamic
Voltage Sharing
Snubber designs for static, commutating, and combined dV
dt
stress are shown in Table 2. Circuits switching the line or a
charged capacitor across a blocking triac require the addition
of a series snubber inductor. The snubber must be designed
R
RE1
L
NON-INDUCTIVE
5K
200W
for maximum dV with the minimum circuit inductance. This
T106-6
1K
2W
CARBON
0−6 kV
1/2A
60 Hz
dt
contraint increases the required triac blocking voltage.
*S1
QTY = 6 TO 16 MKP1V130
Table 2. Snubber Designs
Type
dV
dt
c
dV
dt
G
MT1
MT2
MT2
C
G
s
L (mh)
320
0.4
320
8
0
8
Rs Ohm
1820
48
48
Cs (μf)
0.5
0.5
0.5
Damping Ratio
1.14
0.85
.035
Vstep (V)
1200
1200
750
Vpk (V)
1332
1400
1423
tpk (μs)
768
29.8
1230
dV (V/μs)
dt
4.6
103
PEARSON
411I
PROBE
Both
RL Ohm
MT1
1.3
Vci
V
C
μFD
L
μHY
R
Ω
dl/dt
A/μs
Rejects
Tested
1000
4.06
3.4
5.7
100
0/100
1900*
1.05
7.9
5.7
179
0/195
1500
0.002
0.3
10
3000
3/10
* Open S1 to test breakover dl/dt
Note: Divide Rs and dV by 2, multiply Cs by 2 for each triac.
dt
Figure 6.13. dl/dt Test Circuit
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AN1045/D
turn-on. Alternatively, a large triac capable of surviving the
surge can be used.
Ideally, turn-on speed mismatch should not be allowed to
force the slower thyristor into breakdown. An RC snubber
across each thyristor prevents this. In the worst case, one
device turns on instantly while the other switches at the
slowest possible turn-on time. The rate of voltage rise at the
T2
V IR s
, where VI is the maxislower device is roughly dV dt
2L
lpk
IH1
Δ
Q
ΔQ
mum voltage across L. This rate should not allow the voltage to exceed VDRM in less than Tgt to prevent breakover.
But what if the thyristors are operated without a snubber, or
if avalanche occurs because of a transient overvoltage
condition?
The circuit in Figure 13 was constructed to investigate
this behavior. The capacitor, resistor, and inductor create a
pulse forming network to shape the current wave. The initial voltage on the capacitor was set by a series string of
sidac bidirectional breakover devices.
Test results showed that operation of the triac switch was
safe as long as the rate of current rise was below 200 A/μs.
This was true even when the devices turned on because of
breakover. However, a 0.002 μf capacitor with no series
limiting impedance was sufficient to cause damage in the
Q3 firing polarity.
Circuit malfunctions because of breakover will be temporary if the triac is not damaged. Test results suggest that
there will be no damage when the series inductance is sufficient to hold dl/dt to acceptable values. Highly energetic
transients such as those resulting from lightning strikes can
cause damage to the thyristor by I2t surge overstress.
Device survival requires the use of voltage limiting devices
IH2
T1
ωt = 0
DQ for turn-off at I
t2
H
t2
I pk SINwt dt DQ t1
I pk
w
(cos wt 1 cos wt 2)
t1
I H1 I pk Sinwt 1
I H1
thus t 1 1 Sin 1
w
I pk
Worst case : I H2 0; f 2 wt 2 p
DQ DQ in the circuit and dV limiting snubbers to prevent unwanted
I pk
w
(1 cos[SIN 1
1
w
I pk
I
I H1
])
I pk
I H1
I pk
2
Figure 6.14. Forward Recovery Charge for Turn-Off at lH
dt
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RC Snubber Networks
For Thyristor
Power Control and
Transient Suppression
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By George Templeton
Thyristor Applications Engineer
APPLICATION NOTE
INTRODUCTION
Edited and Updated
dV
dt
RC networks are used to control voltage transients that
could falsely turn-on a thyristor. These networks are called
snubbers.
The simple snubber consists of a series resistor and
capacitor placed around the thyristor. These components
along with the load inductance form a series CRL circuit.
Snubber theory follows from the solution of the circuit’s
differential equation.
Many RC combinations are capable of providing acceptable performance. However, improperly used snubbers can
cause unreliable circuit operation and damage to the semiconductor device.
Both turn-on and turn-off protection may be necessary
for reliability. Sometimes the thyristor must function with a
range of load values. The type of thyristors used, circuit
configuration, and load characteristics are influential.
Snubber design involves compromises. They include
cost, voltage rate, peak voltage, and turn-on stress. Practical solutions depend on device and circuit physics.
DEVICE PHYSICS
s
Static dV turn-on is a consequence of the Miller effect
dt
and regeneration (Figure 1). A change in voltage across the
junction capacitance induces a current through it. This cur-
dt rent is proportional to the rate of voltage change dV . It
triggers the device on when it becomes large enough to
raise the sum of the NPN and PNP transistor alphas to unity.
A
A
IB
CJ
P
CJ
N
I1
IC
N
IC
IJ
G
PB
t
dV
dt
IA 1 (aN ap)
NE
CJ
TWO TRANSISTOR MODEL
OF
SCR
CEFF Figure 6.1.
152
C
CJ
N
K
retain a blocking state under the influence of a voltage
transient.
dv
dt
G
IB
WHAT IS STATIC dV ?
dt
Static dV is a measure of the ability of a thyristor to
dt
NB
P
I2
NPN
STATIC dV
dt
August, 1999 − Rev. 2
IJ
PE
V
PNP
IK
© Semiconductor Components Industries, LLC, 1999
IA
P
CJ
1(aN ap)
dV
dt
s
K
INTEGRATED
STRUCTURE
Model
Publication Order Number:
AN1048/D
AN1048/D
170
CONDITIONS INFLUENCING dV
dt s
150
Transients occurring at line crossing or when there is no
initial voltage across the thyristor are worst case. The collector junction capacitance is greatest then because the
depletion layer widens at higher voltage.
Small transients are incapable of charging the selfcapacitance of the gate layer to its forward biased threshold
voltage (Figure 2). Capacitance voltage divider action
between the collector and gate-cathode junctions and builtin resistors that shunt current away from the cathode emitter are responsible for this effect.
MAC 228A10
VPK = 800 V
STATIC dV (V/ μs)
dt
130
110
90
70
50
30
10
25
40
70
85
100
115
130
145
TJ, JUNCTION TEMPERATURE (°C)
180
Figure 6.3. Exponential
160
MAC 228A10 TRIAC
TJ = 110°C
140
STATIC dV (V/ μs)
dt
55
dV
dt
120
dV
versus Temperature
dt
s
FAILURE MODE
s
Occasional unwanted turn-on by a transient may be
acceptable in a heater circuit but isn’t in a fire prevention
sprinkler system or for the control of a large motor. Turn-on
is destructive when the follow-on current amplitude or rate
is excessive. If the thyristor shorts the power line or a
charged capacitor, it will be damaged.
100
80
60
40
20
200
300
400
500
600
100
PEAK MAIN TERMINAL VOLTAGE (VOLTS)
0
Figure 6.2. Exponential
700
Static dV turn-on is non-destructive when series imped-
800
dt
ance limits the surge. The thyristor turns off after a half-
dV
versus Peak Voltage
dt
cycle of conduction. High dV aids current spreading in the
dt
s
thyristor, improving its ability to withstand dI. Breakdown
dt
turn-on does not have this benefit and should be prevented.
Static dV does not depend strongly on voltage for operadt
140
tion below the maximum voltage and temperature rating.
Avalanche multiplication will increase leakage current and
120
reduce dV capability if a transient is within roughly 50 volts
dt
STATIC dV (V/ μs)
dt
of the actual device breakover voltage.
A higher rated voltage device guarantees increased dV at
80
dt
lower voltage. This is a consequence of the exponential rating method where a 400 V device rated at 50 V/μs has a
60
dt
20
rating. However, the same diffusion recipe usually applies
for all voltages. So actual capabilities of the product are not
much different.
Heat increases current gain and leakage, lowering
s
RINTERNAL = 600 Ω
40
higher dV to 200 V than a 200 V device with an identical
dV
,
dt
MAC 228A10
800 V 110°C
100
0
10
100
1000
GATE-MT1 RESISTANCE (OHMS)
dV
Figure 6.4. Exponential dt s versus
Gate to MT1 Resistance
the gate trigger voltage and noise immunity
(Figure 3).
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10,000
AN1048/D
10
MEG
GATE-CATHODE RESISTANCE (OHMS)
IMPROVING dV
dt s
Static dV can be improved by adding an external resistor
dt
from the gate to MT1 (Figure 4). The resistor provides a
path for leakage and dV induced currents that originate in
dt
the drive circuit or the thyristor itself.
Non-sensitive devices (Figure 5) have internal shorting
resistors dispersed throughout the chip’s cathode area. This
design feature improves noise immunity and high temperature blocking stability at the expense of increased trigger
and holding current. External resistors are optional for nonsensitive SCRs and TRIACs. They should be comparable in
size to the internal shorting resistance of the device (20 to
100 ohms) to provide maximum improvement. The internal
resistance of the thyristor should be measured with an ohmmeter that does not forward bias a diode junction.
1
MEG
G
K
100
K
0.01
0.1
1
10
100
STATIC dV (V
ms)
dt
dV
Figure 6.6. Exponential dt versus
s
Gate-Cathode Resistance
A gate-cathode capacitor (Figure 7) provides a shunt
path for transient currents in the same manner as the resistor. It also filters noise currents from the drive circuit and
enhances the built-in gate-cathode capacitance voltage
divider effect. The gate drive circuit needs to be able to
charge the capacitor without excessive delay, but it does
not need to supply continuous current as it would for a
2000
STATIC dV (V/ μs)
dt
A
10
V
10K
0.001
2200
MAC 15-8
VPK = 600 V
1800
MCR22-006
TA = 65°C
1600
1400
resistor that increases dV the same amount. However, the
dt
1200
capacitor does not enhance static thermal stability.
1000
130
800
120
50
60
100
110
70
80
90
TJ, JUNCTION TEMPERATURE (°C)
120
130
STATIC dV (V/ μs)
dt
600
MAC 228A10
800 V 110°C
110
100
dV
Figure 6.5. Exponential dt s versus
Junction Temperature
90
80
70
60
0.001
Sensitive gate TRIACs run 100 to 1000 ohms. With an
external resistor, their dV capability remains inferior to
dt
dt 1
non-sensitive devices because lateral resistance within the
gate layer reduces its benefit.
Sensitive gate SCRs (IGT 200 μA) have no built-in
resistor. They should be used with an external resistor. The
recommended value of the resistor is 1000 ohms. Higher
values reduce maximum operating temperature and dV
0.01
0.1
GATE TO MT1 CAPACITANCE (μF)
dV
Figure 6.7. Exponential dt versus Gate
s
to MT1 Capacitance
dt The maximum dV
s
improvement occurs with a short.
Actual improvement stops before this because of spreading
resistance in the thyristor. An external capacitor of about
0.1 μF allows the maximum enhancement at a higher value
of RGK.
s
(Figure 6). The capability of these parts varies by more than
100 to 1 depending on gate-cathode termination.
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dt .
One should keep the thyristor cool for the highest dV
for sinusoidal currents is given by the slope of the secant
line between the 50% and 0% levels as:
s
Also devices should be tested in the application circuit at
the highest possible temperature using thyristors with the
lowest measured trigger current.
dIdt
dt
tating dV capability is lower when turning off from the posdt
itive direction of current conduction because of device
geometry. The gate is on the top of the die and obstructs
current flow.
Recombination takes place throughout the conduction
period and along the back side of the current wave as it
declines to zero. Turn-off capability depends on its shape. If
dt
2
the current amplitude is small and its zero crossing dI
VMT2-1
G
1
dIdt
PHASE
ANGLE
c
dt dVdt
VLINE
dt crossing, dV
c
Figure 6.8. TRIAC Inductive Load Turn-Off
dV
dt
s
the volume charge begins to influence turn-off, requiring a
larger snubber. When the current is large or has rapid zero
TIME
TIME
c
has little influence. Commutating dI and
dt
delay time to voltage reapplication determine whether turnoff will be successful or not (Figures 11, 12).
c
G
MT1
dV DEVICE PHYSICS
dt c
TOP
A TRIAC functions like two SCRs connected in inverseparallel. So, a transient of either polarity turns it on.
There is charge within the crystal’s volume because of
prior conduction (Figure 9). The charge at the boundaries
of the collector junction depletion layer responsible for
N
P
N
+
N
N
N
Previously
Conducting Side
N
dV
is also present. TRIACs have lower dV
than
dt s
dt c
dV
because of this additional charge.
dt
N
−
N
s
The volume charge storage within the TRIAC depends
on the peak current before turn-off and its rate of zero
dt
REVERSE RECOVERY
CURRENT PATH
crossing dI . In the classic circuit, the load impedance
c
is
becomes limited by dV . At moderate current amplitudes,
Φ
i
c
low, there is little volume charge storage and turn-off
VMT2-1
VOLTAGE/CURRENT
VLINE
A
ms
and the currents resulting from internal charge storage
within the volume of the device (Figure 10). If the reverse
recovery current resulting from both these components is
high, the lateral IR drop within the TRIAC base layer will
forward bias the emitter and turn the TRIAC on. Commu-
been conducting and attempts to turn-off with an inductive
load. The current and voltage are out of phase (Figure 8).
The TRIAC attempts to turn-off as the current drops below
the holding value. Now the line voltage is high and in the
opposite polarity to the direction of conduction. Successful
turn-off requires the voltage across the TRIAC to rise to the
instantaneous line voltage at a rate slow enough to prevent
retriggering of the device.
L
1000
current generated by dV across the collector capacitance
WHAT IS COMMUTATING dV ?
dt
dV
The commutating
rating applies when a TRIAC has
dt
i
6 f I TM
where f = line frequency and ITM = maximum on-state current in the TRIAC.
Turn-off depends on both the Miller effect displacement
TRIAC COMMUTATING dV
dt
R
c
dt
MT2
LATERAL VOLTAGE
DROP
STORED CHARGE
FROM POSITIVE
CONDUCTION
Figure 6.9. TRIAC Structure and Current Flow
at Commutation
and line frequency determine dI . The rate of crossing
c
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VOLTAGE/CURRENT
dtdi
CONDITIONS INFLUENCING dV
dt c
Commutating dV depends on charge storage and recovdt
c
dV
dt
ery dynamics in addition to the variables influencing static
dV. High temperatures increase minority carrier life-time
dt
c
and the size of recovery currents, making turn-off more difficult. Loads that slow the rate of current zero-crossing aid
turn-off. Those with harmonic content hinder turn-off.
TIME
0
VMT2-1
VOLUME
STORAGE
CHARGE
CHARGE
DUE TO
dV/dt
IRRM
Circuit Examples
Figure 13 shows a TRIAC controlling an inductive load
in a bridge. The inductive load has a time constant longer
than the line period. This causes the load current to remain
constant and the TRIAC current to switch rapidly as the line
voltage reverses. This application is notorious for causing
Figure 6.10. TRIAC Current and Voltage
at Commutation
dt
TRIAC turn-off difficulty because of high dI .
c
C
RS
i
E
V
MAIN TERMINAL VOLTAGE (V)
LS
dIdtc
60 Hz
DC MOTOR
−
i
R
L
+
t
RL 8.3 ms
E
Figure 6.13. Phase Controlling a Motor in a Bridge
VT
0
td
High currents lead to high junction temperatures and
rates of current crossing. Motors can have 5 to 6 times the
normal current amplitude at start-up. This increases both
junction temperature and the rate of current crossing, leading to turn-off problems.
The line frequency causes high rates of current crossing
in 400 Hz applications. Resonant transformer circuits are
doubly periodic and have current harmonics at both the primary and secondary resonance. Non-sinusoidal currents
can lead to turn-off difficulty even if the current amplitude
is low before zero-crossing.
TIME
Figure 6.11. Snubber Delay Time
NORMALIZED DELAY TIME
(t d* = W0 td)
0.5
0.2
0.1
0.2
0.02
0.05
0.03
0.02
0.001 0.002
dV
dt
0.05
0.1
RL = 0
M=1
IRRM = 0
FAILURE MODE
c
dV
dt
0.01
V
T 0.005
E
0.1 0.2 0.3 0.5
0.005 0.01 0.02 0.05
c
failure causes a loss of phase control. Temporary
turn-on or total turn-off failure is possible. This can be
destructive if the TRIAC conducts asymmetrically causing a
dc current component and magnetic saturation. The winding
resistance limits the current. Failure results because of
excessive surge current and junction temperature.
1
DAMPING FACTOR
Figure 6.12. Delay Time To Normalized Voltage
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AN1048/D
IMPROVING dV
dt c
Is dt The same steps that improve dV
s
dt aid dV
c
Hs = MMF to saturate = 0.5 Oersted
ML = mean magnetic path length = 4.99 cm.
except
when stored charge dominates turn-off. Steps that reduce
the stored charge or soften the commutation are necessary
then.
Larger TRIACs have better turn-off capability than
smaller ones with a given load. The current density is lower
in the larger device allowing recombination to claim a
greater proportion of the internal charge. Also junction
temperatures are lower.
TRIACs with high gate trigger currents have greater
turn-off ability because of lower spreading resistance in the
gate layer, reduced Miller effect, or shorter lifetime.
The rate of current crossing can be adjusted by adding a
commutation softening inductor in series with the load.
Small high permeability “square loop” inductors saturate
causing no significant disturbance to the load current. The
inductor resets as the current crosses zero introducing a
large inductance into the snubber circuit at that time. This
slows the current crossing and delays the reapplication of
blocking voltage aiding turn-off.
The commutation inductor is a circuit element that
introduces time delay, as opposed to inductance, into the
Is (.5) (4.99)
60 mA.
.4 p 33
SNUBBER PHYSICS
UNDAMPED NATURAL RESONANCE
w0 I
LC
Radians
second
Resonance determines dV and boosts the peak capacitor
dt
voltage when the snubber resistor is small. C and L are
related to one another by ω02. dV scales linearly with ω0
dt
when the damping factor is held constant. A ten to one
reduction in dV requires a 100 to 1 increase in either
dt
component.
DAMPING FACTOR
ρR
2
CL
The damping factor is proportional to the ratio of the
circuit loss and its surge impedance. It determines the trade
circuit. It will have little influence on observed dV at the
dt
off between dV and peak voltage. Damping factors between
device. The following example illustrates the improvement
resulting from the addition of an inductor constructed by
winding 33 turns of number 18 wire on a tape wound core
(52000-1A). This core is very small having an outside
diameter of 3/4 inch and a thickness of 1/8 inch. The delay
time can be calculated from:
ts Hs ML
where :
0.4 p N
dt
0.01 and 1.0 are recommended.
The Snubber Resistor
Damping and dV
dt
When ρ 0.5, the snubber resistor is small, and dV
dt
(N A B 10 8)
where:
E
depends mostly on resonance. There is little improvement
in dV for damping factors less than 0.3, but peak voltage
dt
ts = time delay to saturation in seconds.
B = saturating flux density in Gauss
A = effective core cross sectional area in cm2
N = number of turns.
and snubber discharge current increase. The voltage wave
has a 1-COS (θ) shape with overshoot and ringing. Maximum dV occurs at a time later than t = 0. There is a time
dt
delay before the voltage rise, and the peak voltage almost
doubles.
When ρ 0.5, the voltage wave is nearly exponential in
For the described inductor:
shape. The maximum instantaneous dV occurs at t = 0.
t s (33 turns) (0.076 cm 2 ) (28000 Gauss)
(1 10 –8 ) (175 V) 4.0 ms.
dt
There is little time delay and moderate voltage overshoot.
When ρ 1.0, the snubber resistor is large and dV
dt
The saturation current of the inductor does not need to be
much larger than the TRIAC trigger current. Turn-off failure will result before recovery currents become greater than
this value. This criterion allows sizing the inductor with the
following equation:
depends mostly on its value. There is some overshoot even
through the circuit is overdamped.
High load inductance requires large snubber resistors and
small snubber capacitors. Low inductances imply small
resistors and large capacitors.
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Damping and Transient Voltages
Table 1 shows suggested minimum resistor values estimated (Appendix A) by testing a 20 piece sample from the
four different TRIAC die sizes.
Figure 14 shows a series inductor and filter capacitor
connected across the ac main line. The peak to peak voltage
of a transient disturbance increases by nearly four times.
Also the duration of the disturbance spreads because of
ringing, increasing the chance of malfunction or damage to
the voltage sensitive circuit. Closing a switch causes this
behavior. The problem can be reduced by adding a damping
resistor in series with the capacitor.
100 μH
TRIAC Type
0.05
0.1
μF
V
Rs
Ohms
dI
dt
A/μs
200
300
400
600
800
3.3
6.8
11
39
51
170
250
308
400
400
VOLTAGE
SENSITIVE
CIRCUIT
Reducing dI
dt
+700
V (VOLTS)
Peak VC
Volts
Non-Sensitive Gate
(IGT 10 mA)
8 to 40 A(RMS)
340 V
0 10 μs
Table 1. Minimum Non-inductive Snubber Resistor
for Four Quadrant Triggering.
TRIAC dI can be improved by avoiding quadrant 4
dt
0
triggering. Most optocoupler circuits operate the TRIAC in
quadrants 1 and 3. Integrated circuit drivers use quadrants 2
and 3. Zero crossing trigger devices are helpful because
they prohibit triggering when the voltage is high.
Driving the gate with a high amplitude fast rise pulse
−700
0
10
TIME (μs)
20
increases dI capability. The gate ratings section defines the
dt
Figure 6.14. Undamped LC Filter Magnifies and
Lengthens a Transient
maximum allowed current.
Inductance in series with the snubber capacitor reduces
dI. It should not be more than five percent of the load
dt
inductance to prevent degradation of the snubber’s dV
dt
dI
dt
Non-Inductive Resistor
suppression capability. Wirewound snubber resistors
sometimes serve this purpose. Alternatively, a separate
inductor can be added in series with the snubber capacitor.
It can be small because it does not need to carry the load
current. For example, 18 turns of AWG No. 20 wire on a
T50-3 (1/2 inch) powdered iron core creates a non-saturating 6.0 μH inductor.
A 10 ohm, 0.33 μF snubber charged to 650 volts resulted
The snubber resistor limits the capacitor discharge
current and reduces dI stress. High dI destroys the thyristor
dt
dt
even though the pulse duration is very short.
The rate of current rise is directly proportional to circuit
voltage and inversely proportional to series inductance.
The snubber is often the major offender because of its low
inductance and close proximity to the thyristor.
With no transient suppressor, breakdown of the thyristor
sets the maximum voltage on the capacitor. It is possible to
exceed the highest rated voltage in the device series
because high voltage devices are often used to supply low
voltage specifications.
The minimum value of the snubber resistor depends on
the type of thyristor, triggering quadrants, gate current
amplitude, voltage, repetitive or non-repetitive operation,
and required life expectancy. There is no simple way to predict the rate of current rise because it depends on turn-on
speed of the thyristor, circuit layout, type and size of snubber capacitor, and inductance in the snubber resistor. The
equations in Appendix D describe the circuit. However, the
values required for the model are not easily obtained except
by testing. Therefore, reliability should be verified in the
actual application circuit.
in a 1000 A/μs dI. Replacement of the non-inductive snubdt
ber resistor with a 20 watt wirewound unit lowered the rate
of rise to a non-destructive 170 A/μs at 800 V. The inductor
gave an 80 A/μs rise at 800 V with the non−inductive
resistor.
The Snubber Capacitor
A damping factor of 0.3 minimizes the size of the snubber capacitor for a given value of dV. This reduces the cost
dt
and physical dimensions of the capacitor. However, it raises
voltage causing a counter balancing cost increase.
Snubber operation relies on the charging of the snubber
capacitor. Turn-off snubbers need a minimum conduction
angle long enough to discharge the capacitor. It should be at
least several time constants (RS CS).
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STORED ENERGY
snubber inductor and limits the rate of inrush current if the
Inductive Switching Transients
device does turn on. Resistance in the load lowers dV and
E 1 L I 0 2 Watt-seconds or Joules
2
VPK (Figure 16).
dt
current in Amperes flowing in the
inductor at t = 0.
Resonant charging cannot boost the supply voltage at
turn-off by more than 2. If there is an initial current flowing
in the load inductance at turn-off, much higher voltages are
possible. Energy storage is negligible when a TRIAC turns
off because of its low holding or recovery current.
The presence of an additional switch such as a relay, thermostat or breaker allows the interruption of load current and
the generation of high spike voltages at switch opening. The
energy in the inductance transfers into the circuit capacitance
and determines the peak voltage (Figure 15).
1.4
2.2
E
1.2
dV
dt
2
VPK
1.9
1
NORMALIZED dV
dt
1.8
M = 0.75
M=1
(dVdt)/ (E W0 )
2.1
1.7
0.8
1.6
1.5
M = 0.5
1.4
0.6
1.3
M = 0.25
0.4
L
1.2
VPK
0.2
1
OPTIONAL
M = RS / (RL + RS)
FAST
C
dV I V
I
dt
C PK
0
L
C
0.2
0.4
0.6
DAMPING FACTOR
Damping factor and reverse recovery current determine
the shape of the voltage wave. It is not exponential when
the snubber damping factor is less than 0.5 (Figure 17) or
when significant recovery currents are present.
T h e e n e rg y s t o r e d i n t h e s n u b b e r c a p a c i t o r
transfers to the snubber resistor and
V MT (VOLTS)
2-1
thyristor every time it turns on. The power loss is proportional to frequency (PAV = 120 Ec @ 60 Hz).
CURRENT DIVERSION
The current flowing in the load inductor cannot change
instantly. This current diverts through the snubber resistor
causing a spike of theoretically infinite dV with magnitude
dt
500
400
300
200
1
0.3
LOAD PHASE ANGLE
at turn-off. However, they help to protect the
dt . The load serves as the
ρ = 0.1
ρ = 0.3
ρ=1
0
0
Highly inductive loads cause increased voltage and
ρ=0
0.1
100
0
equal to (IRRM R) or (IH R).
thyristor from transients and dV
0
RS
RL RS
CHARACTERISTIC VOLTAGE WAVES
Capacitor Discharge
c
RRM
1
Figure 6.16. 0 To 63% dV
dt
(b.) Unprotected Circuit
Figure 6.15. Interrupting Inductive Load Current
dV
dt
0.8
M RESISTIVE DIVISION RATIO I
(a.) Protected Circuit
0.9
0
SLOW
Ec 12 C V2
1.1
M=0
I
R
NORMALIZED PEAK VOLTAGE
VPK /E
I0 =
0.7
1.4
2.1
2.8 3.5 4.2
TIME (μs)
4.9
5.6
063% dV
100 V
ms, E 250 V,
dt s
R 0, I RRM 0
L
Figure 6.17. Voltage Waves For Different
Damping Factors
s
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6.3
7
NORMALIZED PEAK VOLTAGE AND
dV
dt
AN1048/D
COMPLEX LOADS
2.8
2.6
2.4
E
dVdt MAX
2.2
2
Many real-world inductances are non-linear. Their core
materials are not gapped causing inductance to vary with
current amplitude. Small signal measurements poorly characterize them. For modeling purposes, it is best to measure
them in the actual application.
Complex load circuits should be checked for transient
voltages and currents at turn-on and off. With a capacitive
load, turn-on at peak input voltage causes the maximum
surge current. Motor starting current runs 4 to 6 times the
steady state value. Generator action can boost voltages
above the line value. Incandescent lamps have cold start
currents 10 to 20 times the steady state value. Transformers
generate voltage spikes when they are energized. Power
factor correction circuits and switching devices create
complex loads. In most cases, the simple CRL model
allows an approximate snubber design. However, there is
no substitute for testing and measuring the worst case load
conditions.
0−63%
dV
dt
1.8
10−63%
1.6
1.4
1.2
1
VPK
10−63
dV
%
dt
0.8
0.6
dVdt
0.4
0.2
0
o
0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2
DAMPING FACTOR (ρ)
(R 0, M 1, I
0)
L
RRM
V PK
dV
dt
NORMALIZED V PK NORMALIZED dV E
E w0
dt
SURGE CURRENTS IN INDUCTIVE CIRCUITS
Figure 6.18. Trade-Off Between VPK and dV
dt
Inductive loads with long L/R time constants cause
asymmetric multi-cycle surges at start up (Figure 20). Triggering at zero voltage crossing is the worst case condition.
The surge can be eliminated by triggering at the zero current crossing angle.
A variety of wave parameters (Figure 18) describe dV
dt
Some are easy to solve for and assist understanding. These
include the initial dV, the maximum instantaneous dV, and
dt
dt
the average dV to the peak reapplied voltage. The 0 to 63%
dt
dV
and 10 to 63%
dt s
dV
dt
c
definitions on device data
240
VAC
sheets are easy to measure but difficult to compute.
20 MHY
i
0.1
Ω
NON-IDEAL BEHAVIORS
i (AMPERES)
CORE LOSSES
The magnetic core materials in typical 60 Hz loads
introduce losses at the snubber natural frequency. They
appear as a resistance in series with the load inductance and
90
0
winding dc resistance (Figure 19). This causes actual dV to
dt
ZERO VOLTAGE TRIGGERING, IRMS = 30 A
be less than the theoretical value.
40
L
R
80
120
TIME (MILLISECONDS)
160
200
Figure 6.20. Start-Up Surge For Inductive Circuit
Core remanence and saturation cause surge currents.
They depend on trigger angle, line impedance, core characteristics, and direction of the residual magnetization. For
example, a 2.8 kVA 120 V 1:1 transformer with a 1.0
ampere load produced 160 ampere currents at start-up. Soft
starting the circuit at a small conduction angle reduces this
current.
Transformer cores are usually not gapped and saturate
easily. A small asymmetry in the conduction angle causes
magnetic saturation and multi-cycle current surges.
C
L DEPENDS ON CURRENT AMPLITUDE, CORE
SATURATION
R INCLUDES CORE LOSS, WINDING R. INCREASES
WITH FREQUENCY
C WINDING CAPACITANCE. DEPENDS ON
INSULATION, WIRE SIZE, GEOMETRY
Figure 6.19. Inductor Model
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Steps to achieve reliable operation include:
1. Supply sufficient trigger current amplitude. TRIACs
have different trigger currents depending on their
quadrant of operation. Marginal gate current or
optocoupler LED current causes halfwave operation.
2. Supply sufficient gate current duration to achieve
latching. Inductive loads slow down the main terminal
current rise. The gate current must remain above the
specified IGT until the main terminal current exceeds
the latching value. Both a resistive bleeder around the
load and the snubber discharge current help latching.
dt 3. Use a snubber to prevent TRIAC dV
c
resistor. The non-inductive snubber circuit is useful when
the load resistance is much larger than the snubber resistor.
RL
RS
e
E
CS
e
τ = (RL + RS) CS
E
V step E
failure.
t=0
4. Minimize designed-in trigger asymmetry. Triggering
must be correct every half-cycle including the first. Use
a storage scope to investigate circuit behavior during the
first few cycles of turn-on. Alternatively, get the gate
circuit up and running before energizing the load.
5. Derive the trigger synchronization from the line instead
of the TRIAC main terminal voltage. This avoids
regenerative interaction between the core hysteresis
and the triggering angle preventing trigger runaway,
halfwave operation, and core saturation.
6. Avoid high surge currents at start-up. Use a current
probe to determine surge amplitude. Use a soft start
circuit to reduce inrush current.
e (t o) E
R
S
R R
L
S
TIME
RS
e t
t (1 e t
t)
RS RL
RESISTOR
COMPONENT
CAPACITOR
COMPONENT
Figure 6.21. Non-Inductive Snubber Circuit
Opto-TRIAC Examples
Single Snubber, Time Constant Design
Figure 22 illustrates the use of the RC time constant
design method. The optocoupler sees only the voltage
across the snubber capacitor. The resistor R1 supplies the
trigger current of the power TRIAC. A worst case design
procedure assumes that the voltage across the power
TRIAC changes instantly. The capacitor voltage rises to
63% of the maximum in one time constant. Then:
DISTRIBUTED WINDING CAPACITANCE
There are small capacitances between the turns and layers of a coil. Lumped together, they model as a single shunt
capacitance. The load inductor behaves like a capacitor at
frequencies above its self-resonance. It becomes ineffective
R 1 C S t 0.63 E where dV is the rated static dV
dt s
dt
dV
dt s
in controlling dV and VPK when a fast transient such as that
dt
for the optocoupler.
resulting from the closing of a switch occurs. This problem
can be solved by adding a small snubber across the line.
1 A, 60 Hz
SELF-CAPACITANCE
A thyristor has self-capacitance which limits dV when the
dt
VCC
load inductance is large. Large load inductances, high power
factors, and low voltages may allow snubberless operation.
Rin 1
2
L = 318 MHY
10 V/μs
6
MOC
3021
4
180
0.1 μF
170 V
2.4 k
2N6073A
1 V/μs
C1
φ CNTL
SNUBBER EXAMPLES
(0.63)(170)
DESIGN dV 0.45V
ms
dt
(2400)(0.1mF)
0.63 (170)
WITHOUT INDUCTANCE
Power TRIAC Example
240 μs
Figure 21 shows a transient voltage applied to a TRIAC
controlling a resistive load. Theoretically there will be an
instantaneous step of voltage across the TRIAC. The only
elements slowing this rate are the inductance of the wiring
and the self-capacitance of the thyristor. There is an exponential capacitor charging component added along with a
decaying component because of the IR drop in the snubber
TIME
dV
(V
ms)
dt
Power TRIAC
Optocoupler
0.99
0.35
Figure 6.22. Single Snubber For Sensitive Gate TRIAC
and Phase Controllable Optocoupler (ρ = 0.67)
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However a power TRIAC along with the optocoupler
should be used for higher load currents.
The optocoupler conducts current only long enough to
trigger the power device. When it turns on, the voltage
between MT2 and the gate drops below the forward threshold voltage of the opto-TRIAC causing turn-off. The opto-
80
coupler sees dV when the power TRIAC turns off later
dt s
LOAD CURRENT (mA RMS)
70
in the conduction cycle at zero current crossing. Therefore,
it is not necessary to design for the lower optocoupler
dV
dt
c
rating. In this example, a single snubber designed
for the optocoupler protects both devices.
2
3
MOC3031
1
4
MCR265−4
40
30
CS = 0.001
20
10
100
1N4001
CS = 0.01
50
NO SNUBBER
1 MHY
VCC
60
0
430 120 V
400 Hz
20
5
6
MCR265−4
51
100 1N4001
30
40
50
60
70
80
TA, AMBIENT TEMPERATURE (°C)
90
100
(RS = 100 Ω, VRMS = 220 V, POWER FACTOR = 0.5)
0.022
μF
Figure 6.24. MOC3062 Inductive Load Current versus TA
A phase controllable optocoupler is recommended with a
power device. When the load current is small, a MAC97A
TRIAC is suitable.
Unusual circuit conditions sometimes lead to unwanted
(50 V/μs SNUBBER, ρ = 1.0)
Figure 6.23. Anti-Parallel SCR Driver
dt operation of an optocoupler in dV
Optocouplers with SCRs
c
mode. Very large cur-
rents in the power device cause increased voltages between
MT2 and the gate that hold the optocoupler on. Use of a
larger TRIAC or other measures that limit inrush current
solve this problem.
Very short conduction times leave residual charge in the
optocoupler. A minimum conduction angle allows recovery
before voltage reapplication.
Anti-parallel SCR circuits result in the same dV across
dt
the optocoupler and SCR (Figure 23). Phase controllable
opto-couplers require the SCRs to be snubbed to their lower
dV rating. Anti-parallel SCR circuits are free from the
dt
charge storage behaviors that reduce the turn-off capability
of TRIACs. Each SCR conducts for a half-cycle and has the
next half cycle of the ac line in which to recover. The turn-
THE SNUBBER WITH INDUCTANCE
off dV of the conducting SCR becomes a static forward
dt
blocking dV for the other device. Use the SCR data sheet
dt
dV rating in the snubber design.
dt s
Consider an overdamped snubber using a large capacitor
whose voltage changes insignificantly during the time
under consideration. The circuit reduces to an equivalent
L/R series charging circuit.
The current through the snubber resistor is:
A SCR used inside a rectifier bridge to control an ac load
will not have a half cycle in which to recover. The available
time decreases with increasing line voltage. This makes the
circuit less attractive. Inductive transients can be suppressed by a snubber at the input to the bridge or across the
SCR. However, the time limitation still applies.
i V
Rt
1 ett ,
and the voltage across the TRIAC is:
e i R S.
The voltage wave across the TRIAC has an exponential
rise with maximum rate at t = 0. Taking its derivative gives
its value as:
OPTO dV
dt c
dV
dt
Zero-crossing optocouplers can be used to switch
inductive loads at currents less than 100 mA (Figure 24).
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0
V RS
L
.
AN1048/D
φ = measured phase angle between line V and load I
RL = measured dc resistance of the load.
Then
Highly overdamped snubber circuits are not practical
designs. The example illustrates several properties:
1. The initial voltage appears completely across the circuit
inductance. Thus, it determines the rate of change of
V RMS
Z
current through the snubber resistor and the initial dV.
I RMS
dt
This result does not change when there is resistance in
the load and holds true for all damping factors.
2. The snubber works because the inductor controls the
rate of current change through the resistor and the rate
of capacitor charging. Snubber design cannot ignore
the inductance. This approach suggests that the snubber
capacitance is not important but that is only true for
this hypothetical condition. The snubber resistor shunts
the thyristor causing unacceptable leakage when the
capacitor is not present. If the power loss is tolerable,
RL2 XL2
XL
L
2 p f Line
XL Z2 RL2 and
.
If only the load current is known, assume a pure inductance.
This gives a conservative design. Then:
L
V RMS
2 p f Line I RMS
where E 2 V RMS.
For example:
E 2 120 170 V; L dV can be controlled without the capacitor. An
dt
120
39.8 mH.
(8 A) (377 rps)
Read from the graph at ρ = 0.6, VPK = (1.25) 170 = 213 V.
example is the soft-start circuit used to limit inrush
current in switching power supplies (Figure 25).
Use 400 V TRIAC. Read dV
dt (ρ0.6)
1.0.
2. Apply the resonance criterion:
RS
E
AC LINE SNUBBER
L
RECTIFIER
BRIDGE
w0 C1
G
C
ER
dV S
L
dt f
AC LINE SNUBBER
L
G
5 10 6 V
S
29.4 10 3 r p s.
(1) (170 V)
1 0.029 m F
w0 2 L
3. Apply the damping criterion:
RS
E
w0 spec dV dV E .
dt (P)
dt
Snubber With No C
RECTIFIER
BRIDGE
RS 2 ρ
C1
dV
dt
Figure 6.25. Surge Current Limiting For
a Switching Power Supply
under the curve. The region is bounded by static dV at low
dt
dI
and delay time at high currents. Reduction
values of
dt c
factor (ρ) giving a suitable trade-off between VPK and dV.
dt
Determine the normalized dV corresponding to the chosen
dt
of the peak current permits operation at higher line
frequency. This TRIAC operated at f = 400 Hz, TJ = 125°C,
and ITM = 6.0 amperes using a 30 ohm and 0.068 μF
snubber. Low damping factors extend operation to higher
damping factor.
The voltage E depends on the load phase angle:
SAFE AREA CURVE
c
Figure 26 shows a MAC15 TRIAC turn-off safe
operating area curve. Turn-off occurs without problem
TRIAC DESIGN PROCEDURE dV
dt c
1. Refer to Figure 18 and select a particular damping
XL
E 2 VRMS Sin (f) where f tan 1
RL
39.8 10 3 1400 ohms.
CL 2 (0.6) 0.029
10 6
dIdt , but capacitor sizes increase. The addition of a small,
c
saturable commutation inductor extends the allowed
current rate by introducing recovery delay time.
where
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One hundred μH is a suggested value for starting the
design. Plug the assumed inductance into the equation for
C. Larger values of inductance result in higher snubber
−ITM = 15 A
resistance and reduced dI. For example:
100
dt
Given E = 240 2 340 V.
( dVdt )c (V/ μs)
dI 6fITM 10 3A
ms
dt c
Pick ρ = 0.3.
10
Then from Figure 18, VPK = 1.42 (340) = 483 V.
Thus, it will be necessary to use a 600 V device. Using the
previously stated formulas for ω0, C and R we find:
WITH COMMUTATION L
1
w0 C
0.1
14
10
18
22
26
30
34
38
dIdt AMPERES
MILLISECOND
42
46
1
0.2464 m F
(201450) 2 (100 10 6)
50
100 10 6 12 ohms
0.2464 10 6
R 2 (0.3)
c
50 10 6 V
S
201450 rps
(0.73) (340 V)
MAC16-8, COMMUTATIONALL 33TURNS# 18,
52000-1ATAPEWOUNDCORE3
4INCHOD
Figure 6.26.
dV
versus dtdI T
dt
c
c
J
VARIABLE LOADS
The snubber should be designed for the smallest load
= 125°C
inductance because dV will then be highest because of its
dt
dependence on ω0. This requires a higher voltage device for
operation with the largest inductance because of the corresponding low damping factor.
STATIC dV DESIGN
dt
Figure 28 describes dV for an 8.0 ampere load at various
There is usually some inductance in the ac main and
power wiring. The inductance may be more than 100 μH if
there is a transformer in the circuit or nearly zero when a
shunt power factor correction capacitor is present. Usually
the line inductance is roughly several μH. The minimum
inductance must be known or defined by adding a series
inductor to insure reliable operation (Figure 27).
dt
power factors. The minimum inductance is a component
added to prevent static dV firing with a resistive load.
dt
8 A LOAD
R
MAC 218A6FP
10
100 μH
20 A
0.33 μF
120 V
60 Hz
0.033 μF
50 V/μs
dV
dt
LS
1
340
V
L
68 Ω
12 Ω
HEATER
ρ
Figure 6.27. Snubbing For a Resistive Load
s
dV
dt
100 V
ms
R
L
Vstep
c
5 V
ms
VPK
dv
dt
V/μs
Ω
MHY
V
V
0.75
15
0.1
170
191
86
0.03
0
39.8
170
325
4.0
0.04
10.6
28.1
120
225
3.3
0.06
13.5
17.3
74
136
2.6
Figure 6.28. Snubber For a Variable Load
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EXAMPLES OF SNUBBER DESIGNS
Table 2 describes snubber RC values for
1
dV
.
dt
s
80 A RMS
Figures 31 and 32 show possible R and C values for a 5.0
dt V/μs dV
c
assuming a pure inductive load.
40 A
0.1
dV
Designs
dt
(E = 340 V, Vpeak = 500 V, ρ = 0.3)
20 A
5.0 V/μs
L
μH
C
μF
47
100
220
500
1000
3.0
50 V/μs
R
Ohm
C
μF
11
0.33
0.15
0.068
0.033
C S ( μ F)
Table 2. Static
100 V/μs
R
Ohm
10
22
51
100
C
μF
R
Ohm
0.15
0.1
0.033
0.015
10
20
47
110
5A
0.01
0.001
0
R S (OHMS)
5A
40 A
80 A
100
10
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
DAMPING FACTOR
0.8
0.9
1
PURE INDUCTIVE LOAD, V 120 V RMS,
I RRM 0
0.3
0.4
0.5
0.6
0.7
DAMPING FACTOR
0.8
0.9
1
PURE INDUCTIVE LOAD, V 120 V RMS,
I RRM 0
The natural frequencies and impedances of indoor ac
wiring result in damped oscillatory surges with typical frequencies ranging from 30 kHz to 1.5 MHz. Surge amplitude depends on both the wiring and the source of surge
energy. Disturbances tend to die out at locations far away
from the source. Spark-over (6.0 kV in indoor ac wiring)
sets the maximum voltage when transient suppressors are
not present. Transients closer to the service entrance or in
heavy wiring have higher amplitudes, longer durations, and
more damping because of the lower inductance at those
locations.
The simple CRL snubber is a low pass filter attenuating
frequencies above its natural resonance. A steady state
sinusoidal input voltage results in a sine wave output at the
same frequency. With no snubber resistor, the rate of roll
off approaches 12 dB per octave. The corner frequency is at
the snubber’s natural resonance. If the damping factor is
low, the response peaks at this frequency. The snubber
resistor degrades filter characteristics introducing an
up-turn at ω = 1 / (RC). The roll-off approaches 6.0
dB/octave at frequencies above this. Inductance in the
snubber resistor further reduces the roll-off rate.
Figure 32 describes the frequency response of the circuit
in Figure 27. Figure 31 gives the theoretical response to a
3.0 kV 100 kHz ring-wave. The snubber reduces the peak
voltage across the thyristor. However, the fast rise input
2.5 A
20 A
0.2
Figure 6.30. Snubber Capacitor For dV = 5.0 V/μs
dt c
10K
10 A
0.1
Transients arise internally from normal circuit operation
or externally from the environment. The latter is particularly frustrating because the transient characteristics are
undefined. A statistical description applies. Greater or
smaller stresses are possible. Long duration high voltage
transients are much less probable than those of lower
amplitude and higher frequency. Environments with infrequent lightning and load switching see transient voltages
below 3.0 kV.
1000
2.5 A
0.6 A
TRANSIENT AND NOISE SUPPRESSION
0.6 A RMS
10 A
causes a high dV step when series inductance is added to the
dt
snubber resistor. Limiting the input voltage with a transient
suppressor reduces the step.
Figure 6.29. Snubber Resistor For dV = 5.0 V/μs
dt c
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AN1048/D
VMT (VOLTS)
2-1
400
In Figure 32, there is a separate suppressor across each
thyristor. The load impedance limits the surge energy delivered from the line. This allows the use of a smaller device
but omits load protection. This arrangement protects each
thyristor when its load is a possible transient source.
WITHOUT 5 μHY
WITH 5 μHY AND
450 V MOV
AT AC INPUT
0
WITH 5 μHY
−400
0
1
2
3
4
5
6
TIME (μs)
Figure 6.31. Theoretical Response of Figure 33 Circuit
to 3.0 kV IEEE 587 Ring Wave (RSC = 27.5 Ω)
VMAX
+10
Figure 6.33. Limiting Line Voltage
VOLTAGE GAIN (dB)
0
−10
100 μH
−20
Vin
−30
−40
10K
WITH 5 μHY
5 μH
10
12
Vout
0.33 μF
WITHOUT 5μHY
1M
100K
FREQUENCY (Hz)
Figure 6.32. Snubber Frequency Response
V out
V in
Figure 6.34. Limiting Thyristor Voltage
It is desirable to place the suppression device directly
across the source of transient energy to prevent the induction of energy into other circuits. However, there is no
protection for energy injected between the load and its controlling thyristor. Placing the suppressor directly across
each thyristor positively limits maximum voltage and snub-
The noise induced into a circuit is proportional to dV
dt
when coupling is by stray capacitance, and dI when the
dt
coupling is by mutual inductance. Best suppression
requires the use of a voltage limiting device along with a
rate limiting CRL snubber.
The thyristor is best protected by preventing turn-on
ber discharge dI .
dt
from dV or breakover. The circuit should be designed for
dt
EXAMPLES OF SNUBBER APPLICATIONS
what can happen instead of what normally occurs.
In Figure 30, a MOV connected across the line protects
many parallel circuit branches and their loads. The MOV
In Figure 35, TRIACs switch a 3 phase motor on and off
and reverse its rotation. Each TRIAC pair functions as a
SPDT switch. The turn-on of one TRIAC applies the differential voltage between line phases across the blocking
device without the benefit of the motor impedance to
constrain the rate of voltage rise. The inductors are added to
defines the maximum input voltage and dI through the load.
dt
dV
and peak voltage
With the snubber, it sets the maximum
dt
across the thyristor. The MOV must be large because there
is little surge limiting impedance to prevent its burn-out.
prevent static dV firing and a line-to-line short.
dt
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SNUBBER
φ1
2
1
100 μH
G
300
4
22 Ω
2W
WIREWOUND
MOC
3081
91
6
0.15
μF
FWD
SNUBBER
1
G
300
4
MOC
3081
91
6
1/3 HP
208 V
3 PHASE
REV
SNUBBER
φ2
2
SNUBBER
ALL MOV’S ARE 275
VRMS
ALL TRIACS ARE
MAC218A10FP
91
G
1
1
6
100 μH
G
300
4
MOC
3081
91
6
MOC
3081
2
4
FWD
43
SNUBBER
2
1
G
300
6
φ3
MOC
3081
91
4
REV
N
Figure 6.35. 3 Phase Reversing Motor
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SNUBBER
2
AN1048/D
Figure 36 shows a split phase capacitor-run motor with
reversing accomplished by switching the capacitor in series
with one or the other winding. The forward and reverse
TRIACs function as a SPDT switch. Reversing the motor
applies the voltage on the capacitor abruptly across the
blocking thyristor. Again, the inductor L is added to prevent
dV
dt
s
less dV capability than similar non-sensitive devices. A
dt
non-sensitive thyristor should be used for high dV .
dt
dV
ratings are 5 to 20 times less
TRIAC commutating
dt
dV
than static
ratings.
dt
firing of the blocking TRIAC. If turn-on occurs, the
forward and reverse TRIACs short the capacitors (Cs)
resulting in damage to them. It is wise to add the resistor RS
to limit the discharge current.
SNUBBER INDUCTOR
D1
D2
120 VAC
OR
240 VAC
REV
0.1
91
91
FWD
0.1
RS
CS
46 V/μs
MAX
115
C1
D3
+
−
D4
RL
3.75
LS 330 V
240 V
0
500 μH 5.6
120 V
MOTOR
1/70 HP
0.26 A
RS
G
C2
+
−
CS
2N6073
Figure 6.37. Tap Changer For Dual Voltage
Switching Power Supply
Phase controllable optocouplers have lower dV ratings
dt
Figure 6.36. Split Phase Reversing Motor
than zero crossing optocouplers and power TRIACs. These
should be used when a dc voltage component is present, or
to prevent turn-on delay.
Figure 37 shows a “ tap changer.” This circuit allows the
operation of switching power supplies from a 120 or 240
vac line. When the TRIAC is on, the circuit functions as a
conventional voltage doubler with diodes D1 and D2 conducting on alternate half-cycles. In this mode of operation,
Zero crossing optocouplers have more dV capability than
dt
power thyristors; and they should be used in place of phase
controllable devices in static switching applications.
inrush current and dI are hazards to TRIAC reliability.
APPENDIX A
dt
dt MEASURING dV
Series impedance is necessary to prevent damage to the
TRIAC.
The TRIAC is off when the circuit is not doubling. In this
state, the TRIAC sees the difference between the line voltage and the voltage at the intersection of C1 and C2. Tran-
dt sients on the line cause dV
s
s
Figure 38 shows a test circuit for measuring the static dV
dt
of power thyristors. A 1000 volt FET switch insures that the
voltage across the device under test (D.U.T.) rises rapidly
from zero. A differential preamp allows the use of a
N-channel device while keeping the storage scope chassis
at ground for safety purposes. The rate of voltage rise is
adjusted by a variable RC time constant. The charging
resistance is low to avoid waveform distortion because of
the thyristor’s self-capacitance but is large enough to pre-
firing of the TRIAC. High
inrush current, dI, and overvoltage damage to the filter
dt
capacitor are possibilities. Prevention requires the addition
of a RC snubber across the TRIAC and an inductor in series
with the line.
vent damage to the D.U.T. from turn-on dI. Mounting the
dt
THYRISTOR TYPES
miniature range switches, capacitors, and G-K network
close to the device under test reduces stray inductance and
allows testing at more than 10 kV/μs.
Sensitive gate thyristors are easy to turn-on because of
their low trigger current requirements. However, they have
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168
AN1048/D
27
VDRM/VRRM SELECT
2W
1000
10 WATT
WIREWOUND
2
X100 PROBE
DUT
DIFFERENTIAL
PREAMP
G
X100 PROBE
20 k
2W
0.33 1000 V
0.047
1000 V
1
RGK
470 pF
dV
dt
VERNIER
MOUNT DUT ON
TEMPERATURE CONTROLLED
Cμ PLATE
0.001
100
2W
0.005
82
2W
1 MEG
0.01
2W
POWER
0.047
TEST
0.1
1N914
MTP1N100
20 V
f = 10 Hz
PW = 100 μs
50 Ω PULSE
GENERATOR
2 W EACH
1.2 MEG
0.47
56
2W
1000
1/4 W
0−1000 V
10 mA
1N967A
18 V
ALL COMPONENTS ARE NON-INDUCTIVE UNLESS OTHERWISE SHOWN
Figure 6.38. Circuit For Static dV Measurement of Power Thyristors
dt
APPENDIX B
dt MEASURING dV
Commercial chokes simplify the construction of the necessary inductors. Their inductance should be adjusted by
increasing the air gap in the core. Removal of the magnetic
pole piece reduces inductance by 4 to 6 but extends the current without saturation.
The load capacitor consists of a parallel bank of 1500
Vdc non-polar units, with individual bleeders mounted at
each capacitor for safety purposes.
An optional adjustable voltage clamp prevents TRIAC
breakdown.
c
A test fixture to measure commutating dV is shown in
dt
Figure 39. It is a capacitor discharge circuit with the load
series resonant. The single pulse test aids temperature control and allows the use of lower power components. The
limited energy in the load capacitor reduces burn and shock
hazards. The conventional load and snubber circuit provides recovery and damping behaviors like those in the
application.
The voltage across the load capacitor triggers the D.U.T.
It terminates the gate current when the load capacitor voltage crosses zero and the TRIAC current is at its peak.
Each VDRM, ITM combination requires different components. Calculate their values using the equations given in
Figure 39.
dt , synchronize the storage scope on the
To measure dV
c
current waveform and verify the proper current amplitude
and period. Increase the initial voltage on the capacitor to
compensate for losses within the coil if necessary. Adjust
the snubber until the device fails to turn off after the first
half-cycle. Inspect the rate of voltage rise at the fastest
passing condition.
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AN1048/D
HG = W AT LOW
+ CLAMP
− CLAMP
TRIAD C30X
50 H, 3500 Ω
910 k
0.1
+5
dV
dt
SYNC
CL −
51
6.2 MEG
2N3904
150 k
2
W
Q3
−5
PEARSON
301 X
+5
360
360
1/2 W
1/2 W
2N3906
2W
51
2
CASE
CONTROLLED
HEATSINK
G
56
2 WATT
1
2W −5
2.2 k
1/2
Ip T
I PK
W 0 V Ci
2 p VCi
TRIAC
UNDER
TEST
LL 2N3904
−
+
Q3
0.22
270 k
V Ci
2
T
W0 I PK
4 p 2C
Figure 6.39.
1k
1k
W0 L
Q1
1N5343
7.5 V
I
LL
dIdt
2N3906
c
0.22
270 k
6f IPK 10 6
A
ms
dV
Test Circuit For Power TRIACs
dt
c
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170
Q1
MR760
2.2 M
2
W
MR760
+
6.2 MEG
2N390
6
0.1
2N3904
CS
62 μF
1 kV
2N3904
2N3906
910 k
2W
Q1
2.2 M
1/2 W
120
2.2 M
2.2 M
120
1/2 W
0.01
2N390
6
0-1 kV 20 mA
2W
2N3904
0.01
CAPACITOR DECADE 1−10 μF, 0.01−1 μ F, 100 pF− 0.01 μ F
51 k
RS
Q3
2W
MR760
C L (NON-POLAR)
51 k
2W
RL
LL
2.2 M, 2W
2.2 M, 2W
NON-INDUCTIVE
RESISTOR DECADE
0−10 k, 1 Ω STEP
LD10-1000-1000
+ 1.5 kV
− 70 mA
AN1048/D
CONSTANTS (depending on the damping factor):
APPENDIX C
dV DERIVATIONS
dt
DEFINITIONS
2.1 No Damping (ρ 0)
w w0
RT a ρ 0
1.0 R T R L R S Total Resistance
2.2 Underdamped (0 ρ 1)
RS
1.1 M RT
w w0 2 a 2 w0
Snubber Divider Ratio
2.3 Critical Damped (ρ 1)
a w0, w 0, R 2
1
Undamped Natural Frequency
L CS
1.2 w0 2.4 Overdamped (ρ 1)
w Damped Natural Frequency
w a 2 w0 2 w0
1.3 a RT
2L
1.4 χ 2 1.6 ρ Wave Decrement Factor
3.0 i (S) CL Initial Current Factor
CL wa0 Damping Factor
2
0
L
RS
I
e
CS
INITIALCONDITIONS
I I RRM
VC 0
S
RT
L
t=0
E RL
1.8 c I –
L
CS
dV Initial instantaneous dV at t 0, ignoring
dt 0
dt
any initial instantaneous voltage step at
t 0 because of I RRM
V OL
2
a RT
ρ2 1
RL
RT
dV
dt
C
S V 0 L c
E
LSI
; e E S
RT
RT
S 2S
1
S 1
S 2
L
L
LC
LC
1.7 V 0 E R S I Initial Voltage drop at t 0
L
across the load
1.9
CL ,
Laplace transforms for the current and voltage in Figure 40
are:
1
2 LI 2
Initial Energy In Inductor
Final Energy In Capacitor
1
2 CV 2
1.5 χ I
E
1 ρ2
Figure 6.40. Equivalent Circuit for Load and Snubber
The inverse laplace transform for each of the conditions
gives:
UNDERDAMPED (Typical Snubber Design)
c. For all damping conditions
4.0 e E V 0
L
Cos (wt) wa
sin (wt)e at c
at
w sin (wt) e
E RS
2.0 When I 0, dV L
dt 0
dV
Maximum instantaneous dV
dt max
dt
(w 2–a 2)
4.1 de V0 2a Cos (wt) sin (wt) e–at
w
L
dt
t max Time of maximum instantaneous dV
dt
t peak Time of maximum instantaneous peak
voltage across thyristor
c Cos (wt)– a sin (wt) e –at
w
!
"
Average dV V PK
t PK Slope of the secant line
dt
from t 0 through V PK
1 tan 1 4.2 t PK w
V PK Maximum instantaneous voltage across the
thyristor.
#
2a 2
ca
w
w
V0
w
L
$
2a V0 L c
When M 0, R S 0, I 0 : w t PK p
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AN1048/D
6.3 V PK E – V0 (1–a t PK)–c t PK e–a t PK
L
2
2
2
4.3 V PK E a a t PK w0 V0 L 2ac V0 L c
w0
When I 0, R L 0, M 1:
4.4
V PK
E
V PK
6.4 Average dV t PK
dt
When I 0, R S 0, M 0
(1 e a t PK)
e(t) rises asymptotically to E. t PK and average dV
dt
do not exist.
V PK
Average dV t PK
dt
1 ATN
4.5 t max w
4.6
w (2ac V0 (w 2 3a 2))
L
V0 (a 3 3aw 2) c(a 2 w 2)
L
3aV0 2c
L
6.5 t max a 2V0 ac
L
When I 0, t max 0
RS
3
4,
For
RT
then dV
dV
dt max
dt 0
dV
V0L2 w02 2ac V0L c2 e–atmax
dt max
NO DAMPING
5.0 e E (1 Cos (w0t)) I sin (w t)
0
C w0
6.6
5.1 de E w0 sin (w0t) I Cos (w0t)
dt
C
5.2
dV
dt
0
I 0 when I 0
C
CEI w0
5.3 t PK APPENDIX D
SNUBBER DISCHARGE dI DERIVATIONS
dt
w0
5.4 V PK E E2 I2
w0 2C 2
OVERDAMPED
1.0 i V PK
dV
t PK
dt AVG
5.6 t max 1 tan 1 w0 EC
w0
I
5.7
dV
dt
I
C
max
E 2w
1.1 i PK VC
S
2 2I 2 w0E when I0
0 C
2.0 i VC
S te –at
LS
VC
S
2.1 i PK 0.736
RS
c
2 V 0L
a
LS
CRITICAL DAMPED
de a V
at
O L (2 at) c(1 at) e
dt
6.2 t PK CS
1 tanh –1 w
1.2 t PK w
a
6.0 e E V0 (1 at)e at cte at
L
2
VC
S a –at sinh (wt)
w LS
w10 p2 when I 0
CRITICAL DAMPING
6.1
max
a V0 (2–a t max) c (1–a t max) e –a t max
L
p tan 1
5.5
dV
dt
c
V0
L
1
2.2 t PK a
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172
e –a t
PK
AN1048/D
UNDERDAMPED
VC
S e –at sin (wt)
3.0 i w LS
3.1 i PK VC
S
CS
LS
NO DAMPING
4.0 i e –a t
VC
S sin (wt)
w LS
4.1 i PK VC
S
PK
1 tan –1 w
3.2 t PK w
a
CS
LS
4.2 t PK p
2w
RS
LS
t=0
VC
S
CS
i
INITIALCONDITIONS :
i 0, V C INITIALVOLTAGE
S
Figure 6.41. Equivalent Circuit for Snubber Discharge
BIBLIOGRAPHY
Bird, B. M. and K. G. King. An Introduction To Power
Electronics. John Wiley & Sons, 1983, pp. 250−281.
Kervin, Doug. “ The MOC3011 and MOC3021,” EB-101,
Motorola Inc., 1982.
Blicher, Adolph. Thyristor Physics. Springer-Verlag, 1976.
McMurray, William. “Optimum Snubbers For Power
Semiconductors,” IEEE Transactions On Industry Applications, Vol. IA-8, September/October 1972.
Gempe, Horst. “Applications of Zero Voltage Crossing
Optically Isolated TRIAC Drivers,” AN982, Motorola Inc.,
1987.
“Guide for Surge Withstand Capability (SWC) Tests,”
ANSI 337.90A-1974, IEEE Std 472−1974.
Rice, L. R. “Why R-C Networks And Which One For Your
Converter,” Westinghouse Tech Tips 5-2.
“IEEE Guide for Surge Voltages in Low-Voltage AC Power
Circuits,” ANSI/IEEE C62.41-1980, IEEE Std 587−1980.
“Saturable Reactor For Increasing Turn-On Switching
Capability,” SCR Manual Sixth Edition, General Electric,
1979.
Ikeda, Shigeru and Tsuneo Araki. “ The dI Capability of
dt
Thyristors,” Proceedings of the IEEE, Vol. 53, No. 8,
August 1967.
Zell, H. P. “Design Chart For Capacitor-Discharge Pulse
Circuits,” EDN Magazine, June 10, 1968.
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AND8005/D
Automatic AC Line Voltage
Selector
Prepared by: Alfredo Ochoa, Alex Lara & Gabriel Gonzalez
Thyristors Applications Engineers
INTRODUCTION
In some cases, appliances and equipment are able to
operate when supplied by two different levels of AC line
voltage to their main terminals (120V or 240V). This is
why, it is very common that appliances and equipment have
mechanical selectors or switches as an option for selecting
the level of voltage needed. Nevertheless, it is also very
common that these types of equipment can suffer extensive
damage caused for not putting the selector in the right
position. To prevent these kind of problems, thyristors can
be used as a solution for making automatic voltage
selectors in order to avoid possibilities of equipment
damage due to over or low voltages AC line supplied to
them. Thyristors can take many forms, but they have
certain things in common. All of them are solid state
switches, which act as open circuits capable of
withstanding the rated voltage until triggered. When they
are triggered, thyristors become low impedance current
paths and remain in that condition (i.e. conduction) until the
current either stops or drops below a minimum value called
the holding level. A useful application of triacs is a direct
replacement for mechanical selectors, relays or switches. In
this application, the triac furnishes on−off control and the
power regulating ability of the triac is not utilized. The
control circuitry for these applications is usually very
simple and these circuits are useful in applications where
simplicity and reliability are important. In addition, as is
© Semiconductor Components Industries, LLC, 1999
November, 1999 − Rev. 0
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APPLICATION NOTE
well known, there is no arcing with the triac, which can also
be very important in some applications.
The main disadvantages of the mechanical switches or
selectors appear when they are driving high current levels
that can cause arcing and sparks on their contacts each time
they are activated or de−activated. Because of these kind of
effects the contacts of the switches get very significantly
damaged causing problems in the functionality of the
equipment or appliances.
DEFINITIONS
Control Transformers. This transformer consists of two
or more windings coupled by a common or mutual
magnetic field. One of these windings, the primary, is
connected to an alternating voltage source. An alternating
flux will be produced whose amplitude will depend on the
primary voltage and number of turns. The mutual flux will
link the other winding, the secondary, in which it will
induce a voltage whose value will depend on the number of
secondary turns. When the numbers of primary and
secondary turns are properly proportioned, almost any
desired voltage ratio or ratio of transformation can be
obtained. This transformer is also widely used in low power
electronic and control circuits. There it performs such
functions as matching the source impedance and its load for
maximum power transfer, isolating one circuit from
another, or isolating direct current while maintaining AC
continuity between two circuits.
174
Publication Order Number:
AND8005/D
AND8005/D
The following schematic diagram shows an automatic
voltage selector for AC voltage supply of 110V/220V and
Control Transformer
220 V/24 V − 250 mA
1N4007
110 V
or
220 V?
load of 10 Amp rms max. Loads can be equipment or any
kind of appliances:
330 W
330 W
330 mF
1N5349
−
1N4735
LM339
10 kW
LM339
10 kW
+
2.4 kW
820 W
−
+
Main
Transformer
110 V
TO LOAD
EQUIPMENT
220 V
MOC3022
2.4 kW
470 W
1 kW
51 W
MAC15A8
470 W
2N2222
10 nF
1 kW
2N2222
MOC3022
1.6 kW
51 W
MAC15A8
10 nF
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AND8005/D
When the main terminals of the equipment are connected
to the AC line voltage, one of the comparators (LM339)
keeps its output at low level and the other one at high level
because of the voltage references connected to their
inverter and non−inverter input pins. Therefore, one of the
transistors (2N2222) is activated allowing current through
the LED of the optocoupler, and which triggers one of the
triacs (MAC15A8) that then provides the right level of AC
line voltage to the main transformer of the equipment by
connecting one of the primary windings through the triac
triggered.
line voltage condition (220V) is from 180 Vrms to 250
Vrms, therefore, the triac that is driving the winding of the
main transformer for 220V would keep itself triggered
whenever the voltage in the control transformer is within
180 and 250 Vrms. Another very important item to take
into consideration is the operational range of environmental
temperature which is from 0°C to 65°C. If the circuit is
working outside of these temperature limits, it very
probably will experience unreliable functionality.
In conclusion, this automatic voltage selector provides a
very important protection for any kind of voltage sensitive
equipment or appliances against the wrong levels of AC
line input voltages. It eliminates the possibility of any
damage in the circuitry of the equipment caused by
connecting low or high voltage to the main terminals. In
addition, the total price of the electronic circuitry is
inexpensive when compared to the cost of the equipment if
it suffers any damage.
The operational range, in the previous circuit, in the low
AC line voltage condition (110V) is from 100 Vrms to 150
Vrms. This means, the triac that is driving the winding of
the main transformer for 110V would keep itself triggered
whenever the input voltage in the control transformer is
within 100 and 150 Vrms. The operation range in high AC
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AND8006/D
Electronic Starter for
Flourescent Lamps
http://onsemi.com
Prepared by: Alfredo Ochoa, Alex Lara & Gabriel Gonzalez
Thyristors Applications Engineers
INTRODUCTION
In lighting applications for fluorescent lamps the choice
of the starter switch to be used is always very important for
the designers: the cost, reliability, ruggedness, and ease to
be driven must always be kept in mind. This is especially
important in lighting circuits where the designer has to
optimize the operating life of the fluorescent lamps by
using the right starter switch.
In the large family of electronic switches, the thyristor
must be considered as a low cost and powerful device for
lighting applications. Thyristors can take many forms, but
they have certain features in common. All of them are solid
state switches that act as open circuits capable of
withstanding the rated voltage until triggered. When they
are triggered, thyristors become low impedance current
paths and remain in that condition (i.e. conduction) until the
current either stops or drops below a minimum value called
the holding level. Once a thyristor has been triggered, the
trigger current can be removed without turning off the
device.
Silicon controlled rectifiers (SCRs) and triacs are both
members of the thyristor family. SCRs are unidirectional
devices while triacs are bi−directional. A SCR is designed
to switch load current in one direction, while a triac is
designed to conduct load currents in either direction.
Structurally, all thyristors consist of several alternating
layers of opposite P and N silicon, with the exact structure
varying with the particular kind of device. The load is
applied across the multiple junctions and the trigger current
is injected at one of them. The trigger current allows the
load current to flow through the device setting up a
regenerative action which keeps the current flowing even
after the trigger is removed.
These characteristics make thyristors extremely useful in
control applications. Compared to a mechanical switch, a
thyristor has a very long service life and very fast turn on
and turn off times. Because of their fast reaction times,
regenerative action, and low resistance, once triggered,
thyristors are useful as power controllers and transient over
© Semiconductor Components Industries, LLC, 1999
November, 1999 − Rev. 0
APPLICATION NOTE
voltage protectors, as well as simply turning devices on and
off. Thyristors are used to control motors, incandescent and
fluorescent lamps, and many other kinds of equipment.
Although thyristors of all sorts are generally rugged,
there are several points to keep in mind when designing
circuits using them. One of the most important parameters
to respect is the devices’ rated limits on rate of change of
voltage and current (dV/dt and di/dt). If these are exceeded,
the thyristor may be damaged or destroyed.
DEFINITIONS
Ambient Sound Levels. Background noise generated by
ballast and other equipment operating in a building.
Arc. Intense luminous discharge formed by the passage
of electric current across a space between electrodes.
Ballast. An electrical device used in fluorescent and high
intensity discharge (HID) fixtures. It furnishes the
necessary starting and operating current to the lamp for
proper performance.
Electrode. Metal filament that emits electrons in a
fluorescent lamp.
Fluorescent lamp. Gas filled lamp in which light is
produced by the interaction of an arc with phosphorus
lining the lamp’s glass tube.
Fluorescent light circuit. Path over which electric
current flows to operate fluorescent lamps. Three major
types of fluorescent lighting circuits are in use today,
preheat, instant start (slimline) and rapid start.
Instant start (slimline). A class of fluorescent. Ballast
provides a high starting voltage surge to quickly light the
lamp. All instant start lamps have a single pin base and can
be used only with instant ballast.
Rapid Start Lamps. Fluorescent lamps that glow
immediately when turned on and reach full brightness in
about 2 seconds.
Preheat Lamp. A fluorescent lamp in which the filament
must be heated before the arc is created.
This application note is designed for Preheat Start Lamp
circuit. The description of the functionality of this Lamp is
described below:
177
Publication Order Number:
AND8006/D
AND8006/D
HOW THE LAMP WORKS (Using the conventional glow−tube starter)
Neon Gas
Starter
Fluorescent
Coating
Coated
Filament
(Argon Gas)
Mercury Droplets
VAC
Ballast
Inductor
The above Figure illustrates a fluorescent lamp with the
conventional glow−tube starter. The glow−tube starter
consists of a bimetallic switch placed in series with the tube
filament which closes to energize the filaments and then
opens to interrupt the current flowing through the ballast
inductor, thereby, generating the high voltage pulse
necessary for starting. The mechanical glow−tube starter is
the circuit component most likely to cause unreliable
starting.
The principle disadvantage of the conventional
glow−tube starter is that it has to open several times in the
filament circuit to interrupt the current flowing through the
ballast inductor in order to generate the high voltage
necessary for turning−on the fluorescent lamp. However,
those interactions decrease the life of the lamp
considerably. Besides, the lamp turns−on in around 3
seconds when it is using the conventional glow−tube starter
and it also causes degradation to the lamp.
On the other hand, the following schematic diagrams
show the electronic circuitry which substitutes the
conventional glow−tube starter for fluorescent lamps
applications of 20 Watts and 40 Watts using a diode, SCR,
and a TVS or zener clipper(s):
Fluorescent Lamp of 20 Watts
Switch
Clipper
SA90A
A
Coated
Filaments
Line (120 V; 60 Hz)
K
MCR100−8
Gate
Diode 1N4003
Fluorescent
Lamp 20 W
Ballast
Inductor
Electronic Starter
Fluorescent Lamp of 40 Watts
White
Switch
Ballast
Inductor
Blue
Clipper
SA170A
30 W
Black
Phase
Line (120 V; 60 Hz)
Coated
Filaments
0.1 mF
Neutral
A
K
Fluorescent
Lamp 40 W
Clipper
SA30A
MCR100−8
Gate
Diode 1N4003
Electronic Starter
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178
AND8006/D
The main reason why the previous circuits are different is
due to the high voltage must be generated for each kind of
lamp. This means, the inductor ballast for fluorescent
lamps of 40 Watts provides higher voltage than the inductor
ballast for lamps of 20 Watts, that is why, the electronic
circuits have to be different. As an observation, even the
conventional glow−tube starters have to be selected
according the power of the lamp, it means, there is not a
general glow−tube starter who can operate for all kinds of
fluorescent lamps.
The following plots show the voltage and current
waveform in the electronic starter circuitry when the
fluorescent lamps is turned−on:
Fluorescent Lamp of 20 Watts:
Vp=160V
Time before the
Lamp turns−on
Vp=78V
Ch1 Voltage
Ch2 Current
Ip=1.2Amp
When the switch is turned−on, the voltage across the
Clipper (SA90A) is the same as the voltage of the AC Line
(Vpeak=160V), and since the Clipper allows current−flow
through itself only once its VBR is reached (100V peak),
the SCR (MCR100−8) turns−on and closes the circuit to
energize the filaments of the fluorescent lamp. At this time,
the current across the circuit is around 1.2A peak, and once
the lamp has got enough heat, it decreases its dynamic
resistance and permits current−flow through itself which
causes the voltage across the Clipper to decrease to around
78 Vpeak. This effect makes the clipper turn off, since the
voltage is less than the VBR of the device (SA90A), and
because the clipper turns off, the SCR also turns−off, and
opens the circuit to interrupt the current flowing through
the ballast inductor, thereby, generating the high voltage
pulse necessary for starting the lamp. The time that the
fluorescent lamp will take before to turn−on is around
400 msecs by using the electronic starter. It is a faster
starter then when the lamp is using the conventional
glow−tube starter.
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AND8006/D
Fluorescent Lamp of 40 Watts:
Vp=230V
Time before the
Lamp turns−on
Vp=140V
Ch1 Voltage
Ch2 Current
Ip=2.1Amp
The operation of the electronic starter circuit of 40 watts
is similar than for 20 watts, the only difference between
them is that the Inductor Ballast of 40 watts generates
higher voltage than the inductor ballast of 20 watts. That is
why the schematic circuit for lamps of 40 watts has two
clippers and one snubber inside its control circuit. Besides,
the current flowing through this circuit is around 2.1A peak
and it appears around 550 msecs (which is the time that the
lamp takes before it turn itself on), longer than in the
electronic starter circuit of 20 watts.
In conclusion the electronic starter circuits (for 20 and 40
watts) are more reliable than the conventional glow−tube
starters since the lamps turn−on faster and more efficiently
increasing their life−time considerably. Besides, the total
price of the electronic devices is comparable with the
current starters (glow−tube).
In summary, it is also important to mention that the range
of the AC voltage supply to the electronic starter circuits
must be from 115Vrms to 130Vrms for operating correctly.
If it is not within this voltage range the circuits may not be
able to operate in the correct way causing unreliable starting of the lamp. Also, extreme environmental temperatures
could effect the right functionality of the electronic starters
but it is a fact that they can operate between 15°C to 40°C.
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AND8007/D
Momentary Solid State
Switch for Split Phase
Motors
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APPLICATION NOTE
Prepared by: Alfredo Ochoa, Alex Lara & Gabriel Gonzalez
Thyristors Applications Engineers
INTRODUCTION
In control applications for motors the choice of the solid
state switch to be used is always very important for the
designers: the cost, reliability, ruggedness, and ease to be
driven must always be kept in mind. This is especially
important in motor control circuits where the designer has
to optimize the circuitry for controlling the motors in the
correct and efficient way.
In the large family of electronic switches, the thyristor
must be considered as a low cost and powerful device for
motor applications. Thyristors can take many forms, but
they have certain features in common. All of them are solid
state switches which act as open circuits capable of
withstanding the rated voltage until triggered. When they
are triggered, thyristors become low impedance current
paths and remain in that condition (i.e. conduction) until the
current either stops or drops below a minimum value called
the holding level. Once a thyristor has been triggered, the
trigger current can be removed without turning off the
device.
Because Thyristors are reliable solid state switches, they
have many applications, especially as controls. A useful
application of triac is as a direct replacement for an AC
mechanical relay. In this application, the triac furnishes
on−off control and the power regulating ability of the triac
is utilized. The control circuitry for this application is
usually very simple, consisting of a source for the gate
signal and some type of small current switch, either
mechanical or electrical. The gate signal can be obtained
from a separate source or directly from the line voltage at
terminal MT2 of the triac.
One of the most common uses for thyristors is to control
AC loads such as electric motors. This can be done either
by controlling the part of each AC cycle when the circuit
conducts current (Phase control) or by controlling the
© Semiconductor Components Industries, LLC, 1999
November, 1999 − Rev. 0
number or cycles per time period when current is conducted
(cycle control). In addition, thyristors can serve as the basis
of relaxation oscillators for timers and other applications.
DEFINITIONS
Split−Phase Motor. Split−Phase motors have two stator
windings, a main winding and an auxiliary winding, with
their axes displaced 90 electrical degrees in space. The
auxiliary winding has a higher resistance−to−reactance
ratio than the main winding, so that the two currents are out
of phase. The stator field thus first reaches a maximum
about the axis of one winding and then somewhat later in
time (about 80 to 85 electrical degrees) reaches a maximum
about the axis of the winding 90 electrical degrees away in
space. The result is a rotating stator field which causes the
motor to start. At about 75 percent of synchronous speed,
the auxiliary winding is cut out by a centrifugal switch.
The below figure shows an schematic representation of a
split−phase motor:
Line
Centrifugal
Switch
Main
Winding
Auxiliary
Winding
When the line voltage is applied, the current flows
through both windings and the result is a rotating stator
field which causes the motor to start. At about 75 percent of
synchronous speed, the auxiliary winding is cut out by a
centrifugal switch.
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Publication Order Number:
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AND8007/D
The following figure shows a conventional schematic
diagram using a relay for controlling a split−phase
fractional horsepower motor (the compressor of a
refrigerator for example):
In the previous figure the thermostat−switch is
controlling the working−cycle of the compressor and it is
dependent on the set point of environment temperature
which has to be selected according to the temperature
needed. The bi−metal switch protects the compressor
against overload and the relay controls the momentary
switch which cuts out the starter winding once the motor
has reached about 75 percent of the synchronous speed
(after around 300 msecs).
The below plot shows the current flowing through the
compressor (1 Phase, 115Vac, 60Hz, 4.1Arms) when it
starts to operate under normal conditions:
Bi−metal Switch
Line
Thermostat
Switch
Start
Winding
Main
Winding
IS
IO
Momentary
Switch
Neutral
This plot shows the total current flowing through the
compressor when it starts to operate and the time in which
the current reaches the maximum value (Is) due to the start
of the motor. After this time (210 msecs) the start winding
is cut out by the momentary switch and then the current
decreases to reach the nominal current of the compressor
(Io=4.1 Arms).
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AND8007/D
The following schematic diagrams show the way triacs can substitute for the relay and how they can be triggered by using
different control options:
Bi−metal Switch
Line
Thermostat
Switch
“Momentary
Solid State
Switch”
Start
Winding
Normal Op.
Winding
MT2
Gate
Main Winding
Solid Connected
to Neutral
MAC8D, M
MT1
Neutral
0
−lg
Non−sensitive Gate TRIAC
Negative Triggering
for Quadrants 2 and 3
−VCC
Logic
Signal
MT2
Gate
MT1
Neutral
Bi−metal Switch
Line
Direct Negative
Logic Driven
by Microcontroller
mC
HC
MT2
RS
Gate
MT1
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MAC8SD, M
CS
AND8007/D
In the first diagram, the triac (MAC8D,M) is making the
function of the conventional relay’s momentary switch, and
it can be triggered by using a transistor as shown in the above
schematic or through the signals of a microcontroller. Since
this triac (MAC8D,M) is a snubber−less device, it does not
need a snubber network for protecting itself against dV/dt
phenomena.
In the second diagram the triac (MAC8SD,M) is also
performing the function of the relay’s momentary switch,
but since this device is a sensitive gate triac, it only needs a
very low Igt current for triggering itself, therefore, this
option is especially useful in applications where the level of
the current signals are small.
On the other hand, the following figure shows a practical
solid state solution for controlling the compressor with the
operating characteristics mentioned previously (1 Phase,
115Vac, 60Hz, 4.1 Arms) :
120 V/14 V
1000 mF
280 W
10 kW
+
−
Neutral
+
1.3 kW
−
10 mF
1000 mF
1N4003
10 kW
LM741C
100 W
510 W
2N6520
10 kW
Bi−metal Switch
Line
Thermostat
Switch
Start
Winding
Normal Op.
Winding
Neutral
MT2
MAC8D, M
MT1
Neutral
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Main Winding
Solid Connected
to Neutral
AND8007/D
When the thermostat switch is activated, the triac
(MAC8D,M) turns−on and allows current flow through the
starter winding. This current is around 20 Arms because at
the start of the motor (see current plot shown previously),
after around 210msec, the triac turns−off and blocks the
current flowing through the starter winding. In that
moment, the total current flowing through the motor
decreases until it reaches the nominal current (4.1 Arms)
and the motor continues operating until the thermostat
switch is switched off.
Since the triac operates for very short times (around 210
msec), it does not need a heat sink, therefore, it can be
placed on the control board without any kind of problems.
In the previous schematic diagram the triac of 8 Arms
(MAC8D,M), was selected based on the nominal and start
current conditions of the compressor previously described
(1 Phase, 115Vac, 60Hz, 4.1Arms). Therefore, it is
important to mention that in these kind of applications, the
triacs must be selected taking into consideration the
characteristics of each kind of motor to control (nominal
and start currents, frequency, Vac, power, etc). Also, it is
important to remember that it is not possible to have a
general reference for selecting the right triacs for each
motor control application.
In conclusion, the solid state solution described
previously, provides a more reliable control than the
conventional momentary switch controlled by a relay since
the thyristors do not cause any kind of sparks when they
start to operate. In addition, the total price of the electronic
components do not exceed the price of the conventional
relay approach.
In summary, it is also important to mention that extreme
environmental temperatures could affect the functionality
of this momentary solid state switch, but it is a fact that the
triac solution is able to operate between 0°C to 65°C.
Another important consideration is to include in the
power circuit of the motor the right overload switch in
order to protect the motor and the triacs against overload
phenomena.
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AND8008/D
Solid State Control
Solutions for Three Phase
1 HP Motor
http://onsemi.com
Prepared by: Alfredo Ochoa, Alex Lara & Gabriel Gonzalez
Thyristors Applications Engineers
INTRODUCTION
In all kinds of manufacturing, it is very common to have
equipment that has three phase motors for doing different
work functions on the production lines. These motor
functions can be extruders, fans, transport belts, mixers,
pumps, air compressors, etc. Therefore, it is necessary to
have equipment for controlling the start and stop of the
motors and in some cases for reversing them. Actually, one
of the most common solutions for performing this control
functions is by using three phase magnetic starters. It
consists of a block with three main mechanical contacts
which provide the power to the three main terminals of the
motor once its coil is energized. However, the magnetic
starter has a lot of disadvantages and the most common
appear when they are driving high current levels that can
cause arcing and sparks on their contacts each time they are
activated or de−activated. Because of these kind of effects
the contacts of the magnetic starters get very significantly
damaged causing problems in their functionality. With time
it can cause bad and inefficient operation of the motors. This
is why, thyristor should be considered as a low cost
alternative and indeed a powerful device for motor control
applications. Thyristors can take many forms but they have
certain features in common. All of them are solid state
switches that act as open circuits capable of withstanding the
rated voltage until triggered. When they are triggered,
thyristors become low impedance current paths and remain
in that condition (i.e. conduction) until the current either
stops or drops below a minimum value called the holding
level. Once a thyristor has been triggered, the trigger current
can be removed without turning off the device.
© Semiconductor Components Industries, LLC, 1999
November, 1999 − Rev. 0
APPLICATION NOTE
DEFINITIONS
Three phase induction motor.
A three phase induction motor consists of a stator
winding and a rotor of one of the two following types: one
type is a squirrel−cage rotor with a winding consisting of
conducting bars embedded in slots in the rotor iron and
short circuited at each end by conducting end rings. The
other type is a wound rotor with a winding similar to and
having the same number of poles as the stator winding, with
the terminals of the winding being connected to the slip
rings or collector rings on the left end of the shaft. Carbon
brushes bearing on these rings make the rotor terminals
available at points external to the motor so that additional
resistance can be inserted in the rotor circuit if desired.
Three phase voltages of stator frequency are induced in
the rotor, and the accompanying currents are determined by
the voltage magnitude and rotor impedance. Because they
are induced by the rotating stator field, these rotor currents
inherently produce a rotor field with the same number of
poles as the stator and rotating at the same speed with
respect to the stationary rotor. Rotor and stator fields are
thus stationary with respect to each other in space, and a
starting torque is produced. If this torque is sufficient to
overcome the opposition to rotation created by the shaft
load the motor will come up to its operating speed. The
operating speed can never equal the synchronous speed of
the stator field.
The following figure shows a three phase 1HP motor
controlled through a conventional magnetic starter which
has an over−load relay for protecting the motor against
over−load phenomena.
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Publication Order Number:
AND8008/D
AND8008/D
Power Schematic
220 Vrms 60 Hz
L1
Start
L2
L3
Stop
A
A
NC
A
A
A
OL
OL
OL
3 Phase
Motor
1 H.P.
When the start button is pushed on, the coil of the
magnetic starter (A) is energized, thereby, the mechanical
switch contacts close allowing current−flow through the
motor which starts it to operate. If the stop button is pushed,
the coil (A) will be de−energized causing the motor to stop
because of the mechanical switch contacts opened. In
addition, if an overload phenomena exists in the circuit of
the motor, the switch contact (NC) of the overload relay
will open de−energizing the coil and protecting the motor
against any kind of damage.
Magnetic starters have a lot of disadvantages like arcing,
corrosion of the switch contacts, sparks, noisy operation,
short life span, etc. Therefore, in some motor applications,
it is not useful to control the motors by using magnetic
starters since the results can be undesirable.
On the other hand, the following schematic diagrams
show how thyristors can perform the same control function
for starting and stopping a three phase 1HP motor. In addition, the diagrams below show an over load circuit for protecting the motor against overload phenomena.
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AND8008/D
Line Voltage
220 Vrms 60 Hz
L2
L1
510 W
To Over Load
Protection Circuit
for Line 1
L3
510 W
MAC8N
MOC3062
Diagram 1
510 W
MAC8N
MOC3062
MAC8N
MOC3062
Current
Transformer
Current
Transformer
To Over Load
Protection Circuit
for Line 3
3 Phase
Motor
1 H.P.
Diagram 1 shows how three triacs (MAC8M) substitute
the mechanical contacts of the conventional magnetic
starter (shown previously) for supplying the power to the
three phase 1HP motor once the triacs are triggered.
It is important to mention that the optocoupler devices
(MOC3061) will supply the signal currents to the triacs and
hence the motor keeping the same phase shifting (120
electrical degrees) between lines. This is because these
optocuplers (MOC3061) have zero crossing circuits within
them.
Another important thing must be considered as a
protection for the triacs (MAC8M) against fast voltage
transients, is a RC network called snubber which consists of
a series resistor and capacitor placed around the triacs.
These components along with the load inductance from a
series CRL circuit.
Many RC combinations are capable of providing
acceptable performance. However, improperly used
snubbers can cause unreliable circuit operation and damage
to the semiconductor device. Snubber design involves
compromises. They include cost, voltage rate, peak
voltage, and turn−on stress. Practical solutions depend on
the device and circuit physics.
Diagram 2 shows an electronic over−load circuit which
provides very reliable protection to the motor against over
load conditions. The control signals for the two electronic
over−load circuits are received from the shunt resistors
connected in parallel to the two current transformers placed
in two of the three main lines (L1, L3) for sensing the
current flowing through the motor when it is operating. The
level of the voltage signals appearing in the shunt resistors
is dependent on the current flowing through each main line
of the motor. Therefore, if it occurs, that an over load
condition in the power circuit of the motor, that voltage
level will increase its value causing the activation of the
electronic over−load circuits which will stop the motor by
protecting it against the over−load condition experienced.
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AND8008/D
Over Load Protection Circuit for Line 1
10 kW
Wire Conductor
Line 1
Diagram 2
2 kW
220 mF
+12 Vdc
1 kW
+12 Vdc
+12 Vdc
0.1 W
Shunt
1 kW
MUR160
−
+
1 kW
−
LM324
LM324
+
+
10 kW
+12 Vdc
LM324
−
MUR160
−12 Vdc
10 kW
−12 Vdc
25 kW
−12 Vdc
+12 Vdc
22 kW
+12 Vdc
+
−
220 mF
Output Signal Connected
to OR Gate’s Input One
MUR160
1 kW
LM324
1 kW
2k
−12 Vdc
4.3 kW
Over Load Protection Circuit for Line 3
10 kW
2 kW
220 mF
Wire Conductor
Line 3
+12 Vdc
1 kW
+12 Vdc
+12 Vdc
0.1 W
Shunt
MUR160
−
+
1 kW
1 kW
−
LM324
LM324
+
+
10 kW
+12 Vdc
LM324
−
MUR160
−12 Vdc
10 kW
−12 Vdc
25 kW
−12 Vdc
+12 Vdc
22 kW
+12 Vdc
MUR160
+
−
220 mF
Output Signal Connected
to OR Gate’s Input Two
LM324
1 kW
2k
−12 Vdc
4.3 kW
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1 kW
AND8008/D
Start/Stop Control Circuit
Output Signal from
Over Load Protection
Line 1
Diagram 3
MC14075
Output Signal from
Over Load Protection
Line 3
Stop +12 Vdc
Button
+12 Vdc
510 W
CD
MC14013
1 kW
+12 Vdc
Start
Button
1.5 kW
2N2222
SD
MOC3062
MOC3062
1 kW
Diagram 3 shows the main electronic control circuit for
controlling the start and stop of the motor each time it is
needed. If the start button is pushed on, the Flip Flop
(MC14013) is activated triggering the transistor (2N2222)
which turns on the optocoupler’s LED’s which in turn the
three triacs (MAC8M) get triggered and finally starts the
motor. The motor will stop to operate, whenever the stop
MOC3062
Q
button is pushed or any overload condition occurs in the
power circuit of the motor.
The following plot shows the motor’s start current
waveform on one of the three phases when the motor starts
to operate under normal operation conditions and without
driving any kind of mechanical load:
Ipk = 28.8 Amp
start current
Ipk = 2.8 Amp
Normal operation
128 msec
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AND8008/D
This other plot shows the motor’s start current waveform
of the three phases when the motor start to operate under
normal operation conditions and without mechanical load.
Phase R start
current Waveform
Phase S start
current Waveform
Phase T start
current Waveform
The previous plots show the maximum start current IPK
of the motor when it starts to operate and how long it takes
before the current reaches its nominal value. Here, It is
important to mention that the triacs (MAC8N) were
selected by taking into consideration the motor’s start
current value as well as the ITSM capability of these
devices. Therefore, if it is needed to control motors with
higher power (more than 1HP), first, it would be necessary
to characterize them in order to know their current
characteristics. Next be able to select the right triacs for
controling the motor without any kind of problems.
Another important item must be considered if it is needed
to control motors with higher power. These are the
electronic over−load circuits, which have to be adjusted
taking into consideration the level of overload current that
is needed to protect, and is dependent on the kind of motor
that is being controlled.
Based in the previous diagrams and plots, it has been
proven that triacs can substitute the function of the
magnetic starters for starting and stopping a three phase
1HP motor as well as for protecting it against overload
conditions.
The following schematics show a solid state solution for
controlling and reversing a three phase 1HP motor:
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AND8008/D
Reverse Control Schematic
Schematic 1
+12 Vdc
+12 Vdc
Right
Left
1 kW
+12 Vdc
Stop
From Over Load
Protection Circuit
S
MC14013
MC14013
S
1 kW
Q
R
Q
R
MC14075
MC14075
1 kW
MC14075
+12 Vdc
+12 Vdc
10 kW
+12 Vdc
10 kW
−
+12 Vdc
220 mF
510 W
LM339
+
1.5 kW
2k
Right
2N2222
4.3 kW
MOC3062
3
+12 Vdc
+12 Vdc
MOC3062
2
+12 Vdc
510 W
10 kW
10 kW
−
+12 Vdc
220 mF
MUR160
LM339
Left
+
1.5 kW
MOC3062
1
2N2222
2k
MOC3062
4
MOC3062
5
4.3 kW
Schematic 1 shows the control diagram for controlling
and reversing the motor depending on which direction it is
needed to operate. If the right−button is pushed−on, the
triacs number 1, 2, and 3 (shown in the schematic 2) will be
activated, thereby, the motor will operate in the right
direction. If the left button is pushed−on, the triacs
numbered 1, 4, and 5 will be activated causing the left
operation of the motor. Because of the design of the control
circuit, it is possible to reverse the motor without stopping
it once it is operating in right direction. This means, it is not
necessary to stop the motor in order to reverse itself.
MUR160
Nevertheless, it is important to mention that the control
circuit takes a delay−time (of around 3 seconds) before it
activates the other triacs (1,4,5) for reversing the motor.
This delay is to assure that the triacs operating (1,2,3) will
be completely in the off state before it turns−on those other
triacs. This delay−time is very important because if the
triacs for reversing the motor are activated before the other
triacs triggered have reached their completely turned−off
state, it may cause a big short circuit between phases. If this
happens the triacs will be damaged.
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AND8008/D
Power Schematic
Schematic 2
220 Vrms 60 Hz
MOC3062
1
510 W
MOC3062
2
51 W
MOC3062
3
10 nF
510 W
10 nF
51 W
510 W
MOC3062
4
10 nF
To Over Load
Circuit 1
51 W
MAC8N
51 W
MAC8N
510 W
L3
MAC8N
51 W
MAC8N
510 W
L2
MAC8N
L1
MOC3062
5
10 nF
10 nF
To Over Load
Circuit 2
3 Phase
Motor
1 H.P.
• Small size and light weight.
• Safety − freedom form arcing and spark initiated
Schematic 2 shows the power diagram for reversing a
three phase 1HP motor. The way it makes this reverse
function control is by changing the phases−order supplied
to the motor through the triacs (number 4 and 5) and it is
based in the motorís principle for reversing itself. This
diagram also shows two current transformer placed in two
of the three main lines of the motor for sending the control
signals to the electronic overload circuit described
previously. So this means, that the same overload concept
is applicable to these schematics as well as the motor’s start
current waveforms and characteristics shown and
explained previously.
In conclusion, it is proven that thyristors can substitute to
the magnetic starters for making three phase motor control
function in more efficient ways. Because thyristors are
very reliable power switches, they can offer many
advantages in motor applications. Some of the advantages
of triacs as replacements for relays include:
• High Commutating di/dt and High Immunity to dv/dt
@ 125°C
explosions.
• Long life span − contact bounce and burning
eliminated.
• Fast operation − turn−on in microseconds and turn−off
in milliseconds.
• Quiet operation.
The above mentioned points are only some of the big
advantages that can be had if thyristors are used for making
motor control function. Besides, the total cost of the
previous control and power circuits does not exceed to the
cost of the conventional magnetic starters.
One more consideration is that extreme environmental
temperatures could effect the functionality of the electronic
control circuits described herein. Therefore, if the
operation is needed under extreme ambient temperatures,
the designer must evaluate the parameter variation of all the
electronic devices in order to assure the right operation in
the application circuit.
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AND8015/D
Long Life Incandescent
Lamps using SIDACs
Prepared by: Alfredo Ochoa, Alex Lara & Gabriel Gonzalez
Thyristor Application Engineers
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APPLICATION NOTE
Abstract
conducting state when the applied voltage of either polarity
exceeds the breakover voltage. As in other trigger devices,
the SIDAC switches through a negative resistance region to
the low voltage on−state and will remain on until the main
terminal current is interrupted or drops below the holding
current.
SIDAC’s are available in the large MKP3V series and the
economical, easy to insert, small MKP1V series axial lead
packages. Breakdown voltages ranging from 110 to 250V
are available. The MKP3V devices feature bigger chips and
provide much greater surge capability along with somewhat higher RMS current ratings.
The high voltage and current ratings of SIDACs make
them ideal for high energy applications where other trigger
devices are unable to function alone without the aid of additional power boosting components.
The following figure shows the idealized SIDAC
characteristics:
Since the invention of the incandescent lamp bulb by the
genius Thomas A. Edison in 1878, there has been little
changes in the concept. Nowadays we are currently use
them in our houses, and they are part of our comfort but,
since we are more environmentally conscious and more
demanding on energy cost saving products, along with their
durability, we present here an application concept involved
this simple incandescent lamp bulb in conjunction with the
Bilateral Trigger semiconductor device called SIDAC,
offering an alternative way to save money in energy consumption and also giving a longer life time to the lamp
bulbs.
Theory of the SIDAC
The SIDAC is a high voltage bilateral trigger device that
extends the trigger capabilities to significantly higher voltages and currents than have been previously obtainable,
thus permitting new, cost effective applications. Being a
bilateral device, it will switch from a blocking state to a
ITM
VTM
Slope = Rs
IH
IS
IDRM VS
I(BO)
V(BO)
VDRM
Rs = (V(BO) − VS)
(IS − I(BO))
Once the input voltage exceeds V(BO), the device will
switch on to the forward on−voltage VTM of typically 1.1
V and can conduct as much as the specified repetitive peak
on state current ITSM of 20A (10μs pulse, 1KHz repetition
frequency).
© Semiconductor Components Industries, LLC, 1999
January, 2000 − Rev. 0
SIDACs can be used in many applications as transient
protectors, Over Voltage Protectors, Xeon flasher, relaxation oscillators, sodium vapor lamp starters, etc.
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Publication Order Number:
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AND8015/D
This paper explains one of the most typical applications
for SIDACs which is a long life circuit for incandescent
lamps.
The below schematic diagrams show the configurations
of a SIDAC used in series with an incandescent lamp bulb
through a fixed phase for the most typical levels of ac line
voltages:
Option 1: ac line voltage 110V, 60Hz or 50Hz
SIDAC
MKP1V120RL
100 WATTS
110V
AC Line
110V, 60 Hz
Option 2: ac line voltage 220V, 60Hz or 50 Hz
SIDAC
MKP1V120RL
100 WATTS
220V
AC Line
220V, 60 Hz
This is done in order to lower the RMS voltage to the filament, and prolong the life of the bulb. This is particularly
useful when lamps are used in hard to reach locations such
as outdoor lighting in signs where replacement costs are
high. Bulb life span can be extended by 1.5 to 5 times
depending on the type of lamp, the amount of power reduction to the filament, and the number of times the lamp is
switched on from a cold filament condition.
The operating cost of the lamp is also reduced because of
the lower power to the lamp; however, a higher wattage
bulb is required for the same lumen output. The maximum
possible energy reduction is 50% if the lamp wattage is not
increased. The minimum conduction angle is 90° because
the SIDAC must switch on before the peak of the line voltage. Line regulation and breakover voltage tolerances will
require that a conduction angle longer than 90° be used, in
order to prevent lamp turn−off under low line voltage
conditions. Consequently, practical conduction angles will
run between 110° and 130° with corresponding power
reductions of 10% to 30%.
The following plots show the basic voltage and current
waveforms in the SIDAC and load:
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Incandescent Lamp of 100W, 110V, 60Hz
Ch1 Voltage
Vpk = 123V
V(BO)
Ch2 Current
Ipk = 0.96A
−V(BO)
Conduction
Angle
Incandescent Lamp of 50W, 220V, 60Hz
Ch1 Voltage
Vpk = 121V
V(BO)
Ch2 Current
Ipk = 0.33A
−V(BO)
Conduction
Angle
In both previous cases, once the ac line voltage reaches
the V(BO) of the SIDAC (MKP1V120RL), it allows current flow to the incandescent lamp causing the turn−on of
this at some specific phase−angle which is determined by
the SIDAC because of its V(BO).
The fast turn−on time of the SIDAC will result in the generation of RFI which may be noticeable on AM radios operated in the vicinity of the lamp. This can be prevented by
the use of an RFI filter. A possible filter can be the following: connect an inductor (100μH) in series with the SIDAC
and a capacitor (0.1μF) in parallel with the SIDAC and
inductor. This filter causes a ring wave of current through
the SIDAC at turn on time. The filter inductor must be
selected for resonance at a frequency above the upper frequency limit of human hearing and as low below the start of
the AM broadcast band as possible for maximum harmonic
attenuation. In addition, it is important that the filter inductor be non−saturating to prevent di/dt damage to the
SIDAC.
The sizing of the SIDAC must take into account the RMS
current of the lamp, thermal properties of the SIDAC, and
the cold start surge current of the lamp which is often 10 to
20 times the steady state load current. When lamps burn
out, at the end of their operating life, very high surge currents which could damage the SIDAC are possible because
of arcing within the bulb. The large MKP3V device is recommended if the SIDAC is not to be replaced along with
the bulb.
In order to establish what will be the average power that
an incandescent lamp is going to offer if a SIDAC
(MKP1V120RL) is connected in series within the circuit,
some ideal calculations could be made for these purposes
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Example: Incandescent lamp of 100W (120V, 60Hz).
200
v(t):
i(t) x 100:
VL(t):
Voltage / Current
100
v(t): Voltage waveform in the SIDAC
l(t): Portion of current waveform applied to the load
(Multiplied by a factor of 100 to make it more graphically
visible)
VL(t): Voltage waveform in the Load
0
−100
−200
0
0.002
0.004
0.006
0.008
time in seconds
In this case, the conduction angle is around 130°
(6 msecs) in each half cycle of the sinusoidal current waveform, therefore, the average power of the lamp can be
obtained by calculating the following operations:
i
eff
v
eff
Based on this, it is possible to observe that the average
power output is a little bit lower than the original power of
the lamp (100W), even though the conduction angle is
being reduced because of the SIDAC.
In conclusion, when a SIDAC is used to phase control an
incandescent lamp, the operation life of the bulb is going to
be extended by 1.5 to 5 times which represents a big economical advantage when compared to the total cost of the
lamp if it is changed. In addition, the original power of the
lamp is not going to be reduced considerably which assures
the proper level of illumination for the area in which the
incandescent lamp is being used for. Finally, since the
SIDACs are provided in a very small axial lead package,
they can be mounted within the same place that the incandescent lamp is placed.
8.3310 3
2
T
2
i(t) dt
0
8.3310 3
2
T
2
v(t) dt
0
Pav = ieffVLeff
Pav = 91.357
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AND8017/D
Solid State Control for
Bi−Directional Motors
Prepared by: Alfredo Ochoa, Alex Lara & Gabriel Gonzalez
Thyristor Application Engineers
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APPLICATION NOTE
INTRODUCTION
Since the triac has a positive ’on’ and a zero current ’off’
characteristics, it does not suffer from the contact bounce or
arcing inherent in mechanical switches. The switching
action of the triac is very fast compared to conventional
relays, giving more accurate control. A triac can be triggered by dc, ac, rectified ac or pulses. Because of the low
energy required for triggering a triac, the control circuit can
use any of many low cost solid state devices such as transistors, sensitive gate SCRs and triacs, optically coupled
drivers, and integrated circuits.
Some split phase motors are able to operate in forward
and reverse directions since they have two windings for
these purposes. Depending on which winding is energized,
the motor operates in that direction. These motors are especially used in applications for washing machines, transport
belts, and all kinds of equipment in which the operation in
both directions is needed. One of the most traditional way
to control these kind of motors is through mechanical
relays. Nevertheless, they have a lot of disadvantages
which make them ineffective.
This paper is going to show how triacs can substitute the
function of the mechanical relays for controlling bi−directional motors offering a higher level of quality and reliability for control purposes.
The triac is a three terminal ac semiconductor switch that
is triggered into conduction when a low energy signal is
applied to its gate. Unlike the silicon controlled rectifier or
SCR, the triac will conduct current in either direction when
turned on. The triac also differs from the SCR in that either
a positive or negative gate signal will trigger the triac into
conduction. The triac may be thought of as two complementary SCRs in parallel.
The triac offers the circuit designer an economical and
versatile means of accurately controlling ac power. It has
several advantages over conventional mechanical switches.
DEFINITIONS
The two−phase induction motor consists of a stator with
two windings displaced 90 electrical degrees from each
other in space and squirrel cage rotor or the equivalent. The
ac voltages applied to the two windings are generally phase
displaced from each other 90° in time. When the voltages
magnitudes are equal, the equivalent of balanced two−
phase voltages is applied to the stator. The resultant stator
flux is then similar to a three−phase induction motor. The
motor torque speed curves are also similar to those of a
three−phase motor. The two−phase control motor is usually
built with a high resistance rotor to give a high starting
torque and a dropping torque speed characteristic.
The following schematic diagram shows an ac split phase
motor:
Switch 1
Switch 2
Line
Winding A
© Semiconductor Components Industries, LLC, 1999
January, 2000 − Rev. 0
Winding B
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Publication Order Number:
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AND8017/D
If switch 1 is activated, rotation in one direction is
obtained; if switch 2 is activated, rotation in the other
direction results. Since the torque is a function of the voltage supply, changing the magnitude of this changes the
developed torque of the motor. The stalled torque is
assumed to be linearly proportional to the rms control−
winding voltage.
It is very common to add a resonant L−C circuit
connected between the motor windings in order to damp the
energy stored by each motor winding inductance, avoiding
damage to the switches when the transition from one
direction to the other occurs. In addition, this resonant L−C
circuit helps to have good performance in the motor’s
torque each time it changes its rotation.
The following schematic diagram shows how two triacs
can control the rotation of a split phase motor depending
in which winding is energized. In this case the motor
selected for analysis purposes has the following technical
characteristics: 230Vrms, 1.9 Arms, 1/4 Hp, 60Hz, 1400
RPM.
Split Phase Motor
1/4 Hp, 230 V
RPM 1400
Winding 1
Winding 2
50 mH
220 VAC
60 Hz
MAC210A10FP
2k
G
15 mF
MAC210A10FP
MT2
51 W
MT1
2k
G
MT2
MT1
51 W
MOV
MOV
10 nF
10 k
10 k
MOC3042
10 nF
MOC3042
Direct Negative
Logic Driven by
Microcontroller
mC
HC
The micro is controlling the trigger of the triacs through
optocouplers (MOC3042). The optocoupler protects the
control circuitry (Microcontroller, Logic Gates, etc.) if a
short circuit condition occurs within the power circuitry
since these optocouplers insolate the control part of the
general circuit. The MOVs protects the triacs against to the
high voltage transients caused because of the motor rotation changes, so it is very important to add them in the
power circuit, otherwise the triacs could be damaged easily.
The snubber arrangement provides protection against dV/dt
conditions occurring within the application circuit and the
resonant L−C circuit connected between the motor’s wind-
ings helps to have good performance in the torque of the
motor when it changes its rotation.
In the case that the motor is locked due to some mechanical problem within the application field, the maximum
current peak flowing through the triacs would be 7.2 Amps
(5.02 Amps rms), therefore, the triacs (MAC210A10FP)
would not be damaged since they are able to handle up to
12 A rms.
Nevertheless, it is recommended to add an overload
protector in the power circuit of the motor in order to
protect it against any kind of overload conditions which
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could damage the motor in a short period of time since the
current flowing would be higher than its nominal value.
In conclusion, it has been shown how triacs
(MAC210A10FP) substitute the mechanical relay’s
functions to control bi−directional motors offering many
important advantages like reliable control, quiet operation,
long life span, small size, light weight, fast operation, among
others. These are only some of the big advantages that can be
obtained if thyristors are used to control bi−directional
motors. Besides, the total cost of the electronic circuitry does
not exceed to the cost of the conventional mechanical relays.
A very important consideration is that extreme
environment temperatures could affect the functionality of
the electronic devices, therefore, if operation under extreme
ambient temperatures is needed, the designer must take into
consideration the parameter variation of the electronic
devices in order to establish if any kind of adjustment is
needed within the electronic circuitry.
Another important item to be considered by the designer
is that the triacs have to be mounted on a proper heatsink in
order to assure that the case temperature of the device does
not exceed the specifications shown in the datasheet.
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SECTION 7
MOUNTING TECHNIQUES FOR THYRISTORS
Edited and Updated
Figure 7.1 shows an example of doing nearly everything wrong. A tab mount TO-220 package is shown
being used as a replacement for a TO-213AA (TO-66)
part which was socket mounted. To use the socket, the
leads are bent — an operation which, if not properly done,
can crack the package, break the internal bonding wires,
or crack the die. The package is fastened with a
sheet-metal screw through a 1/4″ hole containing a
fiber-insulating sleeve. The force used to tighten the
screw tends to pull the package into the hole, causing
enough distortion to crack the die. In addition the contact
area is small because of the area consumed by the large
hole and the bowing of the package; the result is a much
higher junction temperature than expected. If a rough
heatsink surface and/or burrs around the hole were
displayed in the illustration, most but not all poor
mounting practices would be covered.
INTRODUCTION
Current and power ratings of semiconductors are
inseparably linked to their thermal environment. Except
for lead-mounted parts used at low currents, a heat
exchanger is required to prevent the junction temperature
from exceeding its rated limit, thereby running the risk of
a high failure rate. Furthermore, the semiconductor
industry’s field history indicated that the failure rate of
most silicon semiconductors decreases approximately by
one half for a decrease in junction temperature from
160°C to 135°C.(1) Guidelines for designers of military
power supplies impose a 110°C limit upon junction
temperature. (2) Proper mounting minimizes the temperature gradient between the semiconductor case and the heat
exchanger.
Most early life field failures of power semiconductors
can be traced to faulty mounting procedures. With metal
packaged devices, faulty mounting generally causes
unnecessarily high junction temperature, resulting in
reduced component lifetime, although mechanical damage has occurred on occasion from improperly mounting
to a warped surface. With the widespread use of various
plastic-packaged semiconductors, the prospect of
mechanical damage is very significant. Mechanical
damage can impair the case moisture resistance or crack
the semiconductor die.
PLASTIC BODY
LEADS
PACKAGE HEATSINK
MICA WASHER
EQUIPMENT
HEATSINK
(1) MIL-HANDBOOK — 2178, SECTION 2.2.
(2) “Navy Power Supply Reliability — Design and Manufacturing
Guidelines” NAVMAT P4855-1, Dec. 1982 NAVPUBFORCEN,
5801 Tabor Ave., Philadelphia, PA 19120.
SOCKET FOR
TO-213AA PACKAGE
SPEED NUT
(PART OF SOCKET)
SHEET METAL SCREW
Figure 7.1. Extreme Case of Improperly Mounting
A Semiconductor (Distortion Exaggerated)
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In many situations the case of the semiconductor must
be electrically isolated from its mounting surface. The
isolation material is, to some extent, a thermal isolator as
well, which raises junction operating temperatures. In
addition, the possibility of arc-over problems is
introduced if high voltages are present. Various regulating
agencies also impose creepage distance specifications
which further complicates design. Electrical isolation thus
places additional demands upon the mounting procedure.
Proper mounting procedures usually necessitate orderly
attention to the following:
TIR = TOTAL INDICATOR READING
SAMPLE
PIECE
TIR
REFERENCE PIECE
Δh
DEVICE MOUNTING AREA
Figure 7.2. Surface Flatness Measurement
1. Preparing the mounting surface
2. Applying a thermal grease (if required)
3. Installing the insulator (if electrical isolation is
desired)
4. Fastening the assembly
5. Connecting the terminals to the circuit
Surface Finish
Surface finish is the average of the deviations both
above and below the mean value of surface height. For
minimum interface resistance, a finish in the range of 50
to 60 microinches is satisfactory; a finer finish is costly to
achieve and does not significantly lower contact resistance. Tests conducted by Thermalloy using a copper
TO-204 (TO-3) package with a typical 32-microinch
finish, showed that heatsink finishes between 16 and
64 μ-in caused less than ± 2.5% difference in interface
thermal resistance when the voids and scratches were
filled with a thermal joint compound.(3) Most commercially available cast or extruded heatsinks will require
spotfacing when used in high-power applications. In
general, milled or machined surfaces are satisfactory if
prepared with tools in good working condition.
In this note, mounting procedures are discussed in
general terms for several generic classes of packages. As
newer packages are developed, it is probable that they
will fit into the generic classes discussed in this note.
Unique requirements are given on data sheets pertaining
to the particular package. The following classes are
defined:
Stud Mount
Flange Mount
Pressfit
Plastic Body Mount
Tab Mount
Surface Mount
Appendix A contains a brief review of thermal
resistance concepts. Appendix B discusses measurement
difficulties with interface thermal resistance tests.
Mounting Holes
Mounting holes generally should only be large enough
to allow clearance of the fastener. The large thick flange
type packages having mounting holes removed from the
semiconductor die location, such as the TO-3, may
successfully be used with larger holes to accommodate an
insulating bushing, but many plastic encapsulated packages are intolerant of this condition. For these packages, a
smaller screw size must be used such that the hole for the
bushing does not exceed the hole in the package.
Punched mounting holes have been a source of trouble
because if not properly done, the area around a punched
hole is depressed in the process. This “crater” in the
heatsink around the mounting hole can cause two
problems. The device can be damaged by distortion of the
package as the mounting pressure attempts to conform it
to the shape of the heatsink indentation, or the device may
only bridge the crater and leave a significant percentage
of its heat-dissipating surface out of contact with the
heatsink. The first effect may often be detected immediately by visual cracks in the package (if plastic), but
usually an unnatural stress is imposed, which results in an
early-life failure. The second effect results in hotter
operation and is not manifested until much later.
MOUNTING SURFACE PREPARATION
In general, the heatsink mounting surface should have a
flatness and finish comparable to that of the semiconductor package. In lower power applications, the heatsink
surface is satisfactory if it appears flat against a straight
edge and is free from deep scratches. In high-power
applications, a more detailed examination of the surface is
required. Mounting holes and surface treatment must also
be considered.
Surface Flatness
Surface flatness is determined by comparing the
variance in height (Δh) of the test specimen to that of a
reference standard as indicated in Figure 7.2. Flatness is
normally specified as a fraction of the Total Indicator
Reading (TIR). The mounting surface flatness, i.e.,
Δh/TIR, if less than 4 mils per inch, normal for extruded
aluminum, is satisfactory in most cases.
(3) Catalog #87-HS-9 (1987), page 8, Thermalloy, Inc., P.O. Box
810839, Dallas, Texas 75381-0839.
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Although punched holes are seldom acceptable in the
relatively thick material used for extruded aluminum
heatsinks, several manufacturers are capable of properly
utilizing the capabilities inherent in both fine-edge
blanking or sheared-through holes when applied to sheet
metal as commonly used for stamped heatsinks. The holes
are pierced using Class A progressive dies mounted on
four-post die sets equipped with proper pressure pads and
holding fixtures.
When mounting holes are drilled, a general practice
with extruded aluminum, surface cleanup is important.
Chamfers must be avoided because they reduce heat
transfer surface and increase mounting stress. However,
the edges must be broken to remove burrs which cause
poor contact between device and heatsink and may
puncture isolation material.
a resistivity of approximately 60°C/W/in whereas air has
1200°C/W/in. Since surfaces are highly pock-marked
with minute voids, use of a compound makes a significant
reduction in the interface thermal resistance of the joint.
However, the grease causes a number of problems, as
discussed in the following section.
To avoid using grease, manufacturers have developed
dry conductive and insulating pads to replace the more
traditional materials. These pads are conformal and
therefore partially fill voids when under pressure.
Thermal Compounds (Grease)
Joint compounds are a formulation of fine zinc or other
conductive particles in the silicone oil or other synthetic
base fluid which maintains a grease-like consistency with
time and temperature. Since some of these compounds do
not spread well, they should be evenly applied in a very
thin layer using a spatula or lintless brush, and wiped
lightly to remove excess material. Some cyclic rotation of
the package will help the compound spread evenly over
the entire contact area. Some experimentation is necessary to determine the correct quantity; too little will not
fill all the voids, while too much may permit some
compound to remain between well mated metal surfaces
where it will substantially increase the thermal resistance
of the joint.
To determine the correct amount, several semiconductor samples and heatsinks should be assembled with
different amounts of grease applied evenly to one side of
each mating surface. When the amount is correct a very
small amount of grease should appear around the
perimeter of each mating surface as the assembly is
slowly torqued to the recommended value. Examination
of a dismantled assembly should reveal even wetting
across each mating surface. In production, assemblers
should be trained to slowly apply the specified torque
even though an excessive amount of grease appears at the
edges of mating surfaces. Insufficient torque causes a
significant increase in the thermal resistance of the
interface.
To prevent accumulation of airborne particulate matter,
excess compound should be wiped away using a cloth
moistened with acetone or alcohol. These solvents should
not contact plastic-encapsulated devices, as they may
enter the package and cause a leakage path or carry in
substances which might attack the semiconductor chip.
The silicone oil used in most greases has been found to
evaporate from hot surfaces with time and become
deposited on other cooler surfaces. Consequently,
manufacturers must determine whether a microscopically
thin coating of silicone oil on the entire assembly will
pose any problems. It may be necessary to enclose
components using grease. The newer synthetic base
greases show far less tendency to migrate or creep than
those made with a silicone oil base. However, their
currently observed working temperature range are less,
Surface Treatment
Many aluminium heatsinks are black-anodized to
improve radiation ability and prevent corrosion. Anodizing results in significant electrical but negligible thermal
insulation. It need only be removed from the mounting
area when electrical contact is required. Heatsinks are
also available which have a nickel plated copper insert
under the semiconductor mounting area. No treatment of
this surface is necessary.
Another treated aluminum finish is iridite, or chromateacid dip, which offers low resistance because of its thin
surface, yet has good electrical properties because it
resists oxidation. It need only be cleaned of the oils and
films that collect in the manufacture and storage of the
sinks, a practice which should be applied to all heatsinks.
For economy, paint is sometimes used for sinks;
removal of the paint where the semiconductor is attached
is usually required because of paint’s high thermal
resistance. However, when it is necessary to insulate the
semiconductor package from the heatsink, hard anodized
or painted surfaces allow an easy installation for low
voltage applications. Some manufacturers will provide
anodized or painted surfaces meeting specific insulation
voltage requirements, usually up to 400 volts.
It is also necessary that the surface be free from all
foreign material, film, and oxide (freshly bared aluminum
forms an oxide layer in a few seconds). Immediately prior
to assembly, it is a good practice to polish the mounting
area with No. 000 steel wool, followed by an acetone or
alcohol rinse.
INTERFACE DECISIONS
When any significant amount of power is being
dissipated, something must be done to fill the air voids
between mating surfaces in the thermal path. Otherwise
the interface thermal resistance will be unnecessarily high
and quite dependent upon the surface finishes.
For several years, thermal joint compounds, often
called grease, have been used in the interface. They have
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they are slightly poorer on thermal conductivity and
dielectric strength and their cost is higher.
Data showing the effect of compounds on several
package types under different mounting conditions is
shown in Table 7.1. The rougher the surface, the more
valuable the grease becomes in lowering contact resistance; therefore, when mica insulating washers are used,
use of grease is generally mandatory. The joint compound
also improves the breakdown rating of the insulator.
greased bare joint and a joint using Grafoil, a dry graphite
compound, is shown in the data of Figure 7.3. Grafoil is
claimed to be a replacement for grease when no electrical
isolation is required; the data indicates it does indeed
perform as well as grease. Another conductive pad
available from Aavid is called KON-DUX. It is made with
a unique, grain oriented, flake-like structure (patent pending). Highly compressible, it becomes formed to
the surface roughness of both of the heatsink and
semiconductor. Manufacturer’s data shows it to provide
an interface thermal resistance better than a metal
interface with filled silicone grease. Similar dry conductive pads are available from other manufacturers. They
are a fairly recent development; long term problems, if
they exist, have not yet become evident.
Conductive Pads
Because of the difficulty of assembly using grease and
the evaporation problem, some equipment manufacturers
will not, or cannot, use grease. To minimize the need for
grease, several vendors offer dry conductive pads which
approximate performance obtained with grease. Data for a
Table 7.1
Approximate Values for Interface Thermal Resistance Data from Measurements Performed
in ON Semiconductor Applications Engineering Laboratory
Dry interface values are subject to wide variation because of extreme dependence upon surface conditions. Unless otherwise noted the
case temperature is monitored by a thermocouple located directly under the die reached through a hole in the heatsink.
(See Appendix B for a discussion of Interface Thermal Resistance Measurements.)
Package Type and Data
JEDEC
Outlines
Description
Interface Thermal Resistance (°C/W)
Test
Torque
In-Lb
Metal-to-Metal
With Insulator
Dry
Lubed
Dry
Lubed
Type
DO-203AA, TO-210AA
TO-208AB
10-32 Stud
7/16″ Hex
15
0.3
0.2
1.6
0.8
3 mil
Mica
DO-203AB, TO-210AC
TO-208
1/4-28 Stud
11/16″ Hex
25
0.2
0.1
0.8
0.6
5 mil
Mica
DO-208AA
Pressfit, 1/2″
—
0.15
0.1
—
—
—
TO-204AA
(TO-3)
Diamond Flange
6
0.5
0.1
1.3
0.36
3 mil
Mica
TO-213AA
(TO-66)
Diamond Flange
6
1.5
0.5
2.3
0.9
2 mil
Mica
TO-126
Thermopad
1/4″ x 3/8″
6
2.0
1.3
4.3
3.3
2 mil
Mica
TO-220AB
Thermowatt
8
1.2
1.0
3.4
1.6
2 mil
Mica
See
Note
1
1, 2
NOTES: 1. See Figures 3 and 4 for additional data on TO-3 and TO-220 packages.
2. Screw not insulated. See Figure 7.
INSULATION CONSIDERATIONS
semiconductor and the heatsink. Heatsink isolation is not
always possible, however, because of EMI requirements,
safety reasons, instances where a chassis serves as a
heatsink or where a heatsink is common to several
non-isolated packages. In these situations insulators are
used to isolate the individual components from the
heatsink. Newer packages, such as the ON Semiconductor
Isolated TO-220 Full Pack, was introduced to save the
equipment manufacturer the burden of addressing the
isolation problem.
Since most power semiconductors use are vertical
device construction it is common to manufacture power
semiconductors with the output electrode (anode, collector or drain) electrically common to the case; the problem
of isolating this terminal from ground is a common one.
For lowest overall thermal resistance, which is quite
important when high power must be dissipated, it is best
to isolate the entire heatsink/semiconductor structure
from ground, rather than to use an insulator between the
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Insulator Thermal Resistance
manufacturers. It is obvious that with some arrangements,
the interface thermal resistance exceeds that of the
semiconductor (junction to case).
Referring to Figure 7.3, one may conclude that when
high power is handled, beryllium oxide is unquestionably the best. However, it is an expensive choice. (It
should not be cut or abraided, as the dust is highly
toxic.) Thermafilm is filled polyimide material which
is used for isolation (variation of Kapton). It is a
popular material for low power applications because of
its low cost ability to withstand high temperatures, and
ease of handling in contrast to mica which chips and
flakes easily.
2
1.6
(1)
1.4
(2)
(3)
(4)
(5)
1.2
1
0.8
0.6
(6)
(7)
0.4
(1) Thermalfilm, .002 (.05) thick.
(2) Mica, .003 (.08) thick.
(3) Mica, .002 (.05) thick.
(4) Hard anodized, .020 (.51) thick.
(5) Aluminum oxide, .062 (1.57) thick.
(6) Beryllium oxide, .062 (1.57) thick.
(7) Bare joint — no finish.
(8) Grafoil, .005 (.13) thick.*
*Grafoil is not an insulating material.
0.2
0
(8)
0
THERMAL RESISTANCE FROM TRANSISTOR CASE
TO MOUNTING SURFACE, Rθ CS (° C/WATT)
THERMAL RESISTANCE FROM TRANSISTOR CASE
TO MOUNTING SURFACE, Rθ CS (° C/WATT)
When an insulator is used, thermal grease is of greater
importance than with a metal-to-metal contact, because
two interfaces exist instead of one and some materials,
such as mica, have a hard, markedly uneven surface. With
many isolation materials reduction of interface thermal
resistance of between 2 to 1 and 3 to 1 are typical when
grease is used.
Data obtained by Thermalloy, showing interface resistance for different insulators and torques applied to
TO-204 (TO-3) and TO-220 packages, are shown in
Figure 7.3, for bare and greased surfaces. Similar
materials to those shown are available from several
1
0.9
0.8
0.7
0.6
0.4
72 145
217 290 362
INTERFACE PRESSURE (psi)
0.2
0
2
(5)
(6)
(7)
(8)
1
(1) Thermalfilm, .022 (.05) thick.
(2) Mica, .003 (.08) thick.
(3) Mica, .002 (.05) thick.
(4) Hard anodized, .020 (.51) thick.
(5) Thermalsil II, .009 (.23) thick.
(6) Thermalsil III, .006 (.15) thick.
(7) Bare joint — no finish.
(8) Grafoil, .005 (.13) thick*
*Grafoil is not an insulating material.
0
0
1
2 (IN-LBS) 4
5
MOUNTING SCREW TORQUE
(IN-LBS)
THERMAL RESISTANCE FROM TRANSISTOR CASE
TO MOUNTING SURFACE, Rθ CS (° C/WATT)
THERMAL RESISTANCE FROM TRANSISTOR CASE
TO MOUNTING SURFACE, Rθ CS (° C/WATT)
(1)
(4)
72 145 217 290 362
INTERFACE PRESSURE (psi)
435
(b). TO-204AA (TO-3)
With Thermal Grease
5
3
1
3
4
5
6
0
2
MOUNTING SCREW TORQUE (IN-LBS)
0
(a). TO-204AA (TO-3)
Without Thermal Grease
(2)
(3)
(6)
(7)
0.1
435
4
(2)
(3)
(5)
(4)
0.3
1
2
3
4
5
6
MOUNTING SCREW TORQUE (IN-LBS)
0
(1)
0.5
5
4
3
(1)
2
1
0
6
(2)
(3)
(4)
(7)
0
1
2
3
4
5
MOUNTING SCREW TORQUE
(IN-LBS)
6
(d). TO-220
With Thermal Grease
(c). TO-220
Without Thermal Grease
Figure 7.3. Interface Thermal Resistance for TO-204, TO-3 and TO-220 Packages using Different Insulating
Materials as a Function of Mounting Screw Torque (Data Courtesy Thermalloy)
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A number of other insulating materials are also shown.
They cover a wide range of insulation resistance, thermal
resistance and ease of handling. Mica has been widely
used in the past because it offers high breakdown voltage
and fairly low thermal resistance at a low cost but it
certainly should be used with grease.
Silicone rubber insulators have gained favor because
they are somewhat conformal under pressure. Their
ability to fill in most of the metal voids at the interface
reduces the need for thermal grease. When first
introduced, they suffered from cut-through after a few
years in service. The ones presently available have solved
this problem by having imbedded pads of Kapton of
fiberglass. By comparing Figures 7.3(c) and 7.3(d), it can
be noted that Thermasil, a filled silicone rubber, without
grease has about the same interface thermal resistance as
greased mica for the TO-220 package.
A number of manufacturers offer silicone rubber
insulators. Table 7.2 shows measured performance of a
number of these insulators under carefully controlled,
nearly identical conditions. The interface thermal resistance extremes are over 2:1 for the various materials. It is
also clear that some of the insulators are much more
tolerant than others of out-of-flat surfaces. Since the tests
were performed, newer products have been introduced.
The Bergquist K-10 pad, for example, is described as
having about 2/3 the interface resistance of the Sil Pad
1000 which would place its performance close to the
Chomerics 1671 pad. AAVID also offers an isolated pad
called Rubber-Duc, however it is only available vulcanized to a heatsink and therefore was not included in
the comparison. Published data from AAVID shows
RθCS below 0.3°C/W for pressures above 500 psi.
However, surface flatness and other details are not
specified so a comparison cannot be made with other data
in this note.
The thermal resistance of some silicone rubber insulators is sensitive to surface flatness when used under a
fairly rigid base package. Data for a TO-204AA (TO-3)
package insulated with Thermasil is shown on Figure 7.4.
Observe that the “worst case” encountered (7.5 mils)
yields results having about twice the thermal resistance of
the “typical case” (3 mils), for the more conductive
insulator. In order for Thermasil III to exceed the
performance of greased mica, total surface flatness must
be under 2 mils, a situation that requires spot finishing.
INTERFACE THERMAL RESISTANCE °( C/W)
1.2
Wakefield
Bergquist
Stockwell Rubber
Bergquist
Thermalloy
Shin-Etsu
Bergquist
Chomerics
Wakefield
Bergquist
Ablestik
Thermalloy
Chomerics
Product
Delta Pad 173-7
Sil Pad K-4
1867
Sil Pad 400-9
Thermalsil II
TC-30AG
Sil Pad 400-7
1674
Delta Pad 174-9
Sil Pad 1000
Thermal Wafers
Thermalsil III
1671
RθCS @
3 Mils*
RθCS @
7.5 Mils*
.790
.752
.742
.735
.680
.664
.633
.592
.574
.529
.500
.440
.367
1.175
1.470
1.015
1.205
1.045
1.260
1.060
1.190
.755
.935
.990
1.035
.655
(1)
(2)
0.8
0.6
0.4
(1) Thermalsil II, .009 inches (.23 mm) thick.
(2) Thermalsil III, .006 inches (.15 mm) thick.
0.2
0
0
0.002
0.004
0.006
0.008
0.01
TOTAL JOINT DEVIATION FROM FLAT OVER
TO-3 HEADER SURFACE AREA (INCHES)
Data courtesy of Thermalloy
Figure 7.4. Effect of Total Surface Flatness on
Interface Resistance Using Silicon Rubber Insulators
Silicon rubber insulators have a number of unusual
characteristics. Besides being affected by surface flatness
and initial contact pressure, time is a factor. For example,
in a study of the Cho-Therm 1688 pad thermal interface
impedance dropped from 0.90°C/W to 0.70°C/W at the
end of 1000 hours. Most of the change occurred during the
first 200 hours where RθCS measured 0.74°C/W. The
torque on the conventional mounting hardware had
decreased to 3 in-lb from an initial 6 in-lb. With
non-conformal materials, a reduction in torque would
have increased the interface thermal resistance.
Because of the difficulties in controlling all variables
affecting tests of interface thermal resistance, data from
different manufacturers is not in good agreement.
Table 7.3 shows data obtained from two sources. The
relative performance is the same, except for mica which
varies widely in thickness. Appendix B discusses the
variables which need to be controlled. At the time of this
writing ASTM Committee D9 is developing a standard for
interface measurements.
Table 7.2 Thermal Resistance of Silicone Rubber Pads
Manufacturer
1
* Test Fixture Deviation from flat from Thermalloy EIR86-1010.
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206
consist of multiple chips and integrated circuits as well as
the more conventional single chip devices.
The newer insulated packages can be grouped into two
categories. The first has insulation between the semiconductor chips and the mounting base; an exposed area of
the mounting base is used to secure the part. Case 806
(ICePAK) and Case 388 (TO-258AA) (see Figure 7.6) are
examples of parts in this category. The second category
contains parts which have a plastic overmold covering the
metal mounting base. The Fully Isolated, Case 221C,
illustrated in Figure 7.8, is an example of parts in the
second category.
Parts in the first category — those with an exposed
metal flange or tab — are mounted the same as their
non-insulated counterparts. However, as with any mounting system where pressure is bearing on plastic, the
overmolded type should be used with a conical compression washer, described later in this note.
Table 7.3 Performance of Silicon Rubber Insulators
Tested per MIL-I-49456
Measured Thermal Resistance (°C/W)
Material
Thermalloy Data(1)
Berquist Data(2)
0.033
0.082
0.233
—
0.008
—
—
0.009
0.263
0.267
0.329
0.400
0.433
0.500
0.533
0.583
0.200
—
0.400
0.300
—
—
0.440
0.440
Bare Joint, greased
BeO, greased
Cho-Therm, 1617
Q Pad
(non-insulated)
Sil-Pad, K-10
Thermasil III
Mica, greased
Sil-Pad 1000
Cho-therm 1674
Thermasil II
Sil-Pad 400
Sil-Pad K-4
1. From Thermalloy EIR 87-1030
2. From Berquist Data Sheet
FASTENER AND HARDWARE
CHARACTERISTICS
The conclusions to be drawn from all this data is that
some types of silicon rubber pads, mounted dry, will out
perform the commonly used mica with grease. Cost may
be a determining factor in making a selection.
Characteristics of fasteners, associated hardware, and
the tools to secure them determine their suitability for use
in mounting the various packages. Since many problems
have arisen because of improper choices, the basic
characteristics of several types of hardware are discussed
next.
Insulation Resistance
When using insulators, care must be taken to keep the
mating surfaces clean. Small particles of foreign matter
can puncture the insulation, rendering it useless or
seriously lowering its dielectric strength. In addition,
particularly when voltages higher than 300 V are
encountered, problems with creepage may occur. Dust
and other foreign material can shorten creepage distances
significantly; so having a clean assembly area is important. Surface roughness and humidity also lower insulation resistance. Use of thermal grease usually raises the
withstand voltage of the insulating system but excess
must be removed to avoid collecting dust. Because of
these factors, which are not amenable to analysis, hi-pot
testing should be done on prototypes and a large margin of
safety employed.
Compression Hardware
Normal split ring lock washers are not the best choice
for mounting power semiconductors. A typical #6 washer
flattens at about 50 pounds, whereas 150 to 300 pounds is
needed for good heat transfer at the interface. A very
useful piece of hardware is the conical, sometimes called
a Belleville washer, compression washer. As shown in
Figure 7.5, it has the ability to maintain a fairly constant
pressure over a wide range of its physical deflection —
generally 20% to 80%. When installing, the assembler
applies torque until the washer depresses to half its
original height. (Tests should be run prior to setting up the
assembly line to determine the proper torque for the
fastener used to achieve 50% deflection.) The washer will
absorb any cyclic expansion of the package, insulating
washer or other materials caused by temperature changes.
Conical washers are the key to successful mounting of
devices requiring strict control of the mounting force or
when plastic hardware is used in the mounting scheme.
They are used with the large face contacting the packages.
A new variation of the conical washer includes it as part
of a nut assembly. Called a Sync Nut, the patented device
can be soldered to a PC board and the semiconductor
mounted with 6-32 machine screw.(4)
Insulated Electrode Packages
Because of the nuisance of handling and installing the
accessories needed for an insulated semiconductor mounting, equipment manufacturers have longed for cost-effective insulated packages since the 1950’s. The first to
appear were stud mount types which usually have a layer
of beryllium oxide between the stud hex and the can.
Although effective, the assembly is costly and requires
manual mounting and lead wire soldering to terminals on
top of the case. In the late eighties, a number of
electrically isolated parts became available from various
semiconductor manufacturers. These offerings presently
(4) ITW Shakeproof, St. Charles Road, Elgin, IL 60120.
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207
PRESSURE ON PACKAGE (LB-F)
280
must be used in a clearance hole to engage a speednut. If
a self tapping process is desired, the screw type must be
used which roll-forms machine screw threads.
240
200
Rivets
Rivets are not a recommended fastener for any of the
plastic packages. When a rugged metal flange-mount
package is being mounted directly to a heatsink, rivets can
be used provided press-riveting is used. Crimping force
must be applied slowly and evenly. Pop-riveting should
never be used because the high crimping force could
cause deformation of most semiconductor packages.
Aluminum rivets are much preferred over steel because
less pressure is required to set the rivet and thermal
conductivity is improved.
The hollow rivet, or eyelet, is preferred over solid
rivets. An adjustable, regulated pressure press is used such
that a gradually increasing pressure is used to pan the
eyelet. Use of sharp blows could damage the semiconductor die.
160
120
80
40
0
0
20
40
60
80
100
DEFLECTION OF WASHER DURING MOUNTING (%)
Figure 7.5. Characteristics of the Conical
Compression Washers Designed for Use
with Plastic Body Mounted Semiconductors
Clips
Fast assembly is accomplished with clips. When only a
few watts are being dissipated, the small board mounted
or free-standing heat dissipators with an integral clip,
offered by several manufacturers, result in a low cost
assembly. When higher power is being handled, a separate
clip may be used with larger heatsinks. In order to provide
proper pressure, the clip must be specially designed for a
particular heatsink thickness and semiconductor package.
Clips are especially popular with plastic packages such
as the TO-220 and TO-126. In addition to fast assembly,
the clip provides lower interface thermal resistance than
other assembly methods when it is designed for proper
pressure to bear on the top of the plastic over the die. The
TO-220 package usually is lifted up under the die location
when mounted with a single fastener through the hole in
the tab because of the high pressure at one end.
Solder
Until the advent of the surface mount assembly
technique, solder was not considered a suitable fastener
for power semiconductors. However, user demand has led
to the development of new packages for this application.
Acceptable soldering methods include conventional beltfurnace, irons, vapor-phase reflow, and infrared reflow. It
is important that the semiconductor temperature not
exceed the specified maximum (usually 260°C) or the die
bond to the case could be damaged. A degraded die bond
has excessive thermal resistance which often leads to a
failure under power cycling.
Adhesives
Adhesives are available which have coefficients of
expansion compatible with copper and aluminum.(5)
Highly conductive types are available; a 10 mil layer has
approximately 0.3°C/W interface thermal resistance.
Different types are offered: high strength types for
non-field-serviceable systems or low strength types for
field-serviceable systems. Adhesive bonding is attractive
when case mounted parts are used in wave soldering
assembly because thermal greases are not compatible
with the conformal coatings used and the greases foul the
solder process.
Machine Screws
Machine screws, conical washers, and nuts (or syncnuts) can form a trouble-free fastener system for all types
of packages which have mounting holes. However, proper
torque is necessary. Torque ratings apply when dry;
therefore, care must be exercised when using thermal
grease to prevent it from getting on the threads as
inconsistent torque readings result. Machine screw heads
should not directly contact the surface of plastic packages
types as the screw heads are not sufficiently flat to provide
properly distributed force. Without a washer, cracking of
the plastic case may occur.
Plastic Hardware
Most plastic materials will flow, but differ widely in this
characteristic. When plastic materials form parts of the
fastening system, compression washers are highly valuable
to assure that the assembly will not loosen with time and
temperature cycling. As previously discussed, loss of contact
pressure will increase interface thermal resistance.
Self-Tapping Screws
Under carefully controlled conditions, sheet-metal
screws are acceptable. However, during the tapping
process with a standard screw, a volcano-like protrusion
will develop in the metal being threaded; an unacceptable
surface that could increase the thermal resistance may
result. When standard sheet metal screws are used, they
(5) Robert Batson, Elliot Fraunglass and James P. Moran, “Heat Dissipation
Through Thermalloy Conductive Adhesives, ” EMTAS ’83. Conference,
February 1−3, Phoenix, AZ; Society of Manufacturing Engineers, One
SME Drive, P.O. Box 930, Dearborn, MI 48128.
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FASTENING TECHNIQUES
need a spacer or combination spacer and isolation bushing
to raise the screw head above the top surface of the
plastic.
The popular TO-220 Package and others of similar construction lift off the mounting surface as pressure is
applied to one end. (See Appendix B, Figure B1.) To
counter this tendency, at least one hardware manufacturer
offers a hard plastic cantilever beam which applies more
even pressure on the tab.(6) In addition, it separates the
mounting screw from the metal tab. Tab mount parts may
also be effectively mounted with clips as shown in
Figure 7.10(c). To obtain high pressure without cracking
the case, a pressure spreader bar should be used under the
clip. Interface thermal resistance with the cantilever beam
or clips can be lower than with screw mounting.
Each of the various classes of packages in use requires
different fastening techniques. Details pertaining to each
type are discussed in following sections. Some general
considerations follow.
To prevent galvanic action from occurring when devices
are used on aluminum heatsinks in a corrosive atmosphere,
many devices are nickel- or gold-plated. Consequently,
precautions must be taken not to mar the finish.
Another factor to be considered is that when a copper
based part is rigidly mounted to an aluminium heatsink, a
bimetallic system results which will bend with temperature
changes. Not only is the thermal coefficient of expansion
different for copper and aluminium, but the temperature
gradient through each metal also causes each component to
bend. If bending is excessive and the package is mounted by
two or more screws the semiconductor chip could be
damaged. Bending can be minimized by:
(6) Catalog, Edition 18, Richco Plastic Company, 5825 N. Tripp Ave.,
Chicago, IL 60546.
1. Mounting the component parallel to the heatsink fins
to provide increased stiffness.
2. Allowing the heatsink holes to be a bit oversized
so that some slip between surfaces can occur as
temperature changes.
3. Using a highly conductive thermal grease or mounting
pad between the heatsink and semicondutor to minimize
the temperature gradient and allow for movement.
CASE 221A-07
(TO-220AB)
Tab Mount
The tab mount class is composed of a wide array of
packages as illustrated in Figure 7.6. Mounting considerations for all varieties are similar to that for the popular
TO-220 package, whose suggested mounting arrangements and hardware are shown in Figure 7.7. The
rectangular washer shown in Figure 7.7(a) is used to
minimize distortion of the mounting flange; excessive
distortion could cause damage to the semiconductor chip.
Use of the washer is only important when the size of the
mounting hole exceeds 0.140 inch (6−32 clearance).
Larger holes are needed to accommodate the lower
insulating bushing when the screw is electrically connected to the case; however, the holes should not be larger
than necessary to provide hardware clearance and should
never exceed a diameter of 0.250 inch. Flange distortion
is also possible if excessive torque is used during
mounting. A maximum torque of 8 inch-pounds is
suggested when using a 6−32 screw.
Care should be exercised to assure that the tool used to
drive the mounting screw never comes in contact with the
plastic body during the driving operation. Such contact
can result in damage to the plastic body and internal
device connections. To minimize this problem,
ON Semiconductor TO-220 packages have a chamfer on
one end. TO-220 packages of other manufacturers may
CASE 314B
(5 PIN TO-220)
CASE 340-02
(TO-218)
CASE 221B-04
(TO-220AC)
CASE 314D
CASE 387-01
(TO-254AA)
CASE 388-01
(TO-258AA)
CASE 339
CASE 806-05
(ICePAK)
Figure 7.6. Several Types of Tab-Mount Parts
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209
(a). Preferred Arrangement
for Isolated or Non-Isolated
Mounting. Screw is at
Semiconductor Case
Potential. 6-32 Hardware is
Used.
The copper sheet has a hole for mounting; plastic is
molded enveloping the chip but leaving the mounting
hole open. The low thermal resistance of this construction
is obtained at the expense of a requirement that strict
attention be paid to the mounting procedure.
The fully isolated power package (Case 221C-02) is
similar to a TO-220 except that the tab is encased in
plastic. Because the mounting force is applied to plastic,
the mounting procedure differs from a standard TO-220
and is similar to that of the Thermopad.
Several types of fasteners may be used to secure these
packages; machine screws, eyelets, or clips are preferred.
With screws or eyelets, a conical washer should be used
which applies the proper force to the package over a fairly
wide range of deflection and distributes the force over a
fairly large surface area. Screws should not be tightened
with any type of air-driven torque gun or equipment
which may cause high impact. Characteristics of a
suitable conical washer is shown in Figure 7.5.
Figure 7.9 shows details of mounting Case 77 devices.
Clip mounting is fast and requires minimum hardware,
however, the clip must be properly chosen to insure that
the proper mounting force is applied. When electrical
isolation is required with screw mounting, a bushing
inside the mounting hole will insure that the screw threads
do not contact the metal base.
The fully isolated power package, (Case 221C, 221D
and 340B) permits the mounting procedure to be greatly
simplified over that of a standard TO-220. As shown in
Figure 7.10(c), one properly chosen clip, inserted into two
slotted holes in the heatsink, is all the hardware needed.
Even though clip pressure is much lower than obtained
with a screw, the thermal resistance is about the same for
either method. This occurs because the clip bears directly
on top of the die and holds the package flat while the
screw causes the package to lift up somewhat under the
die. (See Figure B1 of Appendix B.) The interface should
consist of a layer of thermal grease or a highly conductive
thermal pad. Of course, screw mounting shown in
Figure 7.10(b) may also be used but a conical compression washer should be included. Both methods afford a
major reduction in hardware as compared to the conventional mounting method with a TO-220 package which is
shown in Figure 7.10(a).
(b). Alternate Arrangement
for Isolated Mounting when
Screw must be at Heat Sink
Potential. 4-40 Hardware is
used.
Use Parts Listed below.
Use Parts Listed
Below
4-40 PAN OR HEX HEAD SCREW
6-32 HEX
HEAD SCREW
FLAT WASHER
INSULATING BUSHING
(1) RECTANGULAR STEEL
WASHER
SEMICONDUCTOR
(CASE 221, 221A)
SEMICONDUCTOR
(CASE 221,221A)
(2) RECTANGULAR
INSULATOR
HEATSINK
(2) BUSHING
RECTANGULAR
INSULATOR
HEATSINK
(3) FLAT WASHER
COMPRESSION WASHER
(4) CONICAL WASHER
6-32 HEX NUT
4-40 HEX NUT
(1) Used with thin chassis and/or large hole.
(2) Used when isolation is required.
(3) Required when nylon bushing is used.
Figure 7.7. Mounting Arrangements for Tab
Mount TO-220
In situations where a tab mount package is making
direct contact with the heatsink, an eyelet may be used,
provided sharp blows or impact shock is avoided.
Plastic Body Mount
The Thermopad and fully isolated plastic power
packages shown in Figure 7.8 are typical of packages in
this group. They have been designed to feature minimum
size with no compromise in thermal resistance. For the
Thermopad (Case 77) parts this is accomplished by
die-bounding the silicon chip on one side of a thin copper
sheet; the opposite side is exposed as a mounting surface.
CASE 77
CASE 221C-02
(TO-225AA/
(Fully Isolated)
TO-126)
(THERMOPAD)
CASE 221D-02
(Fully Isolated)
CASE 340B-03
(Fully Isolated)
Figure 7.8. Plastic Body-Mount Packages
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4-40 SCREW
MACHINE SCREW OR
SHEET METAL SCREW
PLAIN WASHER
INSULATING BUSHING
HEAT SINK
SURFACE
COMPRESSION WASHER
THERMOPAD PACKAGE
INSULATING WASHER
(OPTIONAL)
INSULATOR
HEATSINK
MACHINE OR SPEED
NUT
COMPRESSION WASHER
(a). Machine Screw Mounting
NUT
(a). Screw-Mounted TO-220
6-32 SCREW
EYELET
PLAIN WASHER
COMPRESSION WASHER
INSULATING WASHER
(OPTIONAL)
HEATSINK
COMPRESSION WASHER
NUT
(b). Eyelet Mounting
(b). Screw-Mounted Fully Isolated
CLIP
HEATSINK
(c). Clips
(c). Clip-Mounted Fully Isolated
Figure 7.9. Recommended Mounting Arrangements
for TO-225AA (TO-126) Thermopad Packages
Figure 7.10. Mounting Arrangements for the Fully
Isolated Power Package as Compared to a
Conventional TO-220
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100
RθJA , THERMAL RESISTANCE (° C/W)
Surface Mount
Although many of the tab mount parts have been
surface mounted, special small footprint packages for
mounting power semiconductors using surface mount
assembly techniques have been developed. The DPAK,
shown in Figure 11, for example, will accommodate a die
up to 112 mils x 112 mils, and has a typical thermal
resistance around 2°C/W junction to case. The thermal
resistance values of the solder interface is well under
1°C/W. The printed circuit board also serves as the
heatsink.
Standard Glass-Epoxy 2-ounce boards do not make
very good heatsinks because the thin foil has a high
thermal resistance. As Figure 7.12 shows, thermal
resistance assymtotes to about 20°C/W at 10 square
inches of board area, although a point of diminishing
returns occurs at about 3 square inches.
Boards are offered that have thick aluminium or copper
substrates. A dielectric coating designed for low thermal
resistance is overlayed with one or two ounce copper foil
for the preparation of printed conductor traces. Tests run
on such a product indicate that case to substrate thermal
resistance is in the vicinity of 1°C/W, exact values
depending upon board type.(7) The substrate may be an
effective heatsink itself, or it can be attached to a
conventional finned heatsink for improved performance.
Since DPAK and other surface mount packages are
designed to be compatible with surface mount assembly
techniques, no special precautions are needed other than
to insure that maximum temperature/time profiles are not
exceeded.
60
40
20
0
2
4
6
8
10
PCB PAD AREA (IN2)
Figure 7.12. Effect of Footprint Area on Thermal
Resistance of DPAK Mounted on a Glass-Epoxy Board
FREE AIR AND SOCKET MOUNTING
In applications where average power dissipation is on
the order of a watt or so, most power semiconductors may
be mounted with little or no heatsinking. The leads of the
various metal power packages are not designed to support
the packages; their cases must be firmly supported to
avoid the possibility of cracked seals around the leads.
Many plastic packages may be supported by their leads in
applications where high shock and vibration stresses are
not encountered and where no heatsink is used. The leads
should be as short as possible to increase vibration
resistance and reduce thermal resistance. As a general
practice however, it is better to support the package. A
plastic support for the TO-220 Package and other similar
types is offered by heatsink accessory vendors.
In many situations, because its leads are fairly heavy,
the CASE 77 (TO-225AA)(TO-127) package has supported a small heatsink; however, no definitive data is
available. When using a small heatsink, it is good practice
to have the sink rigidly mounted such that the sink or the
board is providing total support for the semiconductor.
Two possible arrangements are shown in Figure 7.13. The
arrangement of part (a) could be used with any plastic
package, but the scheme of part (b) is more practical with
Case 77 Thermopad devices. With the other package
types, mounting the transistor on top of the heatsink is
more practical.
(7) Herb Fick, “Thermal Management of Surface Mount Power
Devices,” Power conversion and Intelligent Motion, August 1987.
CASE 369-07
PCB, 1/16 IN THICK
G10/FR4, 2 OUNCE
EPOXY GLASS BOARD,
DOUBLE SIDED
80
CASE 369A-13
Figure 7.11. Surface Mount D-PAK Parts
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CONNECTING AND HANDLING TERMINALS
HEATSINK
Pins, leads, and tabs must be handled and connected
properly to avoid undue mechanical stress which could
cause semiconductor failure. Change in mechanical
dimensions as a result of thermal cycling over operating
temperature extremes must be considered. Standard
metal, plastic, and RF stripline packages each have some
special considerations.
TO-225AA
CASE 77
HEATSINK SURFACE
Plastic Packages
TWIST LOCKS
OR
SOLDERABLE
LEGS
CIRCUIT BOARD
The leads of the plastic packages are somewhat flexible
and can be reshaped although this is not a recommended
procedure. In many cases, a heatsink can be chosen which
makes lead-bending unnecessary. Numerous-lead and tabforming options are available from ON Semiconductor on
large quantity orders. Preformed leads remove the users
risk of device damage caused by bending.
If, however, lead-bending is done by the user, several
basic considerations should be observed. When bending
the lead, support must be placed between the point of
bending and the package. For forming small quantities of
units, a pair of pliers may be used to clamp the leads at the
case, while bending with the fingers or another pair of
pliers. For production quantities, a suitable fixture should
be made.
The following rules should be observed to avoid
damage to the package.
1. A leadbend radius greater than 1/16 inch is advisable
for TO-225AA (CASE 77) and 1/32 inch for TO-220.
2. No twisting of leads should be done at the case.
3. No axial motion of the lead should be allowed with
respect to the case.
The leads of plastic packages are not designed to
withstand excessive axial pull. Force in this direction
greater than 4 pounds may result in permanent damage to
the device. If the mounting arrangement imposes axial
stress on the leads, a condition which may be caused by
thermal cycling, some method of strain relief should be
devised. When wires are used for connections, care
should be exercised to assure that movement of the wire
does not cause movement of the lead at the lead-to-plastic
junctions. Highly flexible or braided wires are good for
providing strain relief.
Wire-wrapping of the leads is permissible, provided
that the lead is restrained between the plastic case and
the point of the wrapping. The leads may be soldered;
the maximum soldering temperature, however, must
not exceed 260°C and must be applied for not more than
10 seconds at a distance greater than 1/8 inch from the
plastic case.
(a). Simple Plate, Vertically Mounted
HEATSINK
TO-225AA
CASE 77
HEATSINK
SURFACE
CIRCUIT BOARD
(b). Commercial Sink, Horizontally Mounted
Figure 7.13. Methods of Using Small Heatsinks With
Plastic Semiconductor Packages
In certain situations, in particular where semiconductor
testing is required or prototypes are being developed,
sockets are desirable. Manufacturers have provided
sockets for many of the packages available from
ON Semiconductor. The user is urged to consult manufacturers’ catalogs for specific details. Sockets with Kelvin
connections are necessary to obtain accurate voltage
readings across semiconductor terminals.
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CLEANING CIRCUIT BOARDS
where
It is important that any solvents or cleaning chemicals
used in the process of degreasing or flux removal do not
affect the reliability of the devices. Alcohol and unchlorinated Freon solvents are generally satisfactory for use
with plastic devices, since they do not damage the
package. Hydrocarbons such as gasoline and chlorinated
Freon may cause the encapsulant to swell, possibly
damaging the transistor die.
When using an ultrasonic cleaner for cleaning circuit
boards, care should be taken with regard to ultrasonic
energy and time of application. This is particularly true if
any packages are free-standing without support.
TJ = junction temperature (°C)
TC = case temperature (°C)
RθJC = thermal resistance junctionto-case as specified on the
data sheet (°C/W)
PD = power dissipated in the device (W)
The difficulty in applying the equation often lies in
determining the power dissipation. Two commonly
used empirical methods are graphical integration and
substitution.
Graphical Integration
Graphical integration may be performed by taking
oscilloscope pictures of a complete cycle of the voltage
and current waveforms, using a limit device. The pictures
should be taken with the temperature stabilized. Corresponding points are then read from each photo at a
suitable number of time increments. Each pair of voltage
and current values are multiplied together to give
instantaneous values of power. The results are plotted on
linear graph paper, the number of squares within the curve
counted, and the total divided by the number of squares
along the time axis. The quotient is the average power
dissipation. Oscilloscopes are available to perform these
measurements and make the necessary calculations.
THERMAL SYSTEM EVALUATION
Assuming that a suitable method of mounting the
semiconductor without incurring damage has been
achieved, it is important to ascertain whether the junction
temperature is within bounds.
In applications where the power dissipated in the semiconductor consists of pulses at a low duty cycle, the
instantaneous or peak junction temperature, not average
temperature, may be the limiting condition. In this case,
use must be made of transient thermal resistance data. For
a full explanation of its use, see ON Semiconductor
Application Note, AN569.
Other applications, notably RF power amplifiers or
switches driving highly reactive loads, may create severe
current crowding conditions which render the traditional
concepts of thermal resistance or transient thermal
impedance invalid. In this case, transistor safe operating
area, thyristor di/dt limits, or equivalent ratings as
applicable, must be observed.
Fortunately, in many applications, a calculation of the
average junction temperature is sufficient. It is based on
the concept of thermal resistance between the junction
and a temperature reference point on the case. (See
Appendix A.) A fine wire thermocouple should be used,
such as #36 AWG, to determine case temperature.
Average operating junction temperature can be computed
from the following equation:
Substitution
This method is based upon substituting an easily
measurable, smooth dc source for a complex waveform. A
switching arrangement is provided which allows operating the load with the device under test, until it stabilizes in
temperature. Case temperature is monitored. By throwing
the switch to the “test” position, the device under test is
connected to a dc power supply, while another pole of the
switch supplies the normal power to the load to keep it
operating at full power level. The dc supply is adjusted so
that the semiconductor case temperature remains approximately constant when the switch is thrown to each
position for about 10 seconds. The dc voltage and current
values are multiplied together to obtain average power. It
is generally necessary that a Kelvin connection be used
for the device voltage measurement.
TJ T C R qJC P D
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APPENDIX A
THERMAL RESISTANCE CONCEPTS
The basic equation for heat transfer under steady-state
conditions is generally written as:
q hADT
where
(1)
where
q = rate of heat transfer or power
dissipation (PD)
h = heat transfer coefficient,
A = area involved in heat transfer,
ΔT = temperature difference between
regions of heat transfer.
However, electrical engineers generally find it easier to
work in terms of thermal resistance, defined as the ratio of
temperature to power. From Equation 1, thermal resistance, Rθ, is
Rq DT
q 1
hA
The thermal resistance junction to ambient is the sum of
the individual components. Each component must be
minimized if the lowest junction temperature is to result.
The value for the interface thermal resistance, RθCS,
may be significant compared to the other thermal-resistance terms. A proper mounting procedure can minimize
RθCS.
The thermal resistance of the heatsink is not absolutely
constant; its thermal efficiency increases as ambient
temperature increases and it is also affected by orientation
of the sink. The thermal resistance of the semiconductor is
also variable; it is a function of biasing and temperature.
Semiconductor thermal resistance specifications are normally at conditions where current density is fairly
uniform. In some applications such as in RF power
amplifiers and short-pulse applications, current density is
not uniform and localized heating in the semiconductor
chip will be the controlling factor in determining power
handling ability.
(2)
The coefficient (h) depends upon the heat transfer
mechanism used and various factors involved in that
particular mechanism.
An analogy between Equation (2) and Ohm’s Law is
often made to form models of heat flow. Note that T could
be thought of as a voltage thermal resistance corresponds
to electrical resistance (R); and, power (q) is analogous to
current (I). This gives rise to a basic thermal resistance
model for a semiconductor as indicated by Figure A1.
The equivalent electrical circuit may be analyzed by
using Kirchoff’s Law and the following equation results:
TJ P D(RqJC RqCS RqSA) TA
TJ = junction temperature,
PD = power dissipation
RθJC = semiconductor thermal resistance
(junction to case),
RθCS = interface thermal resistance
(case to heatsink),
RθSA = heatsink thermal resistance
(heatsink to ambient),
TA = ambient temperature.
(3)
TJ, JUNCTION TEMPERATURE
RθJC
DIE
TC, CASE TEMPERATURE
PD
INSULATORS
RθCS
TS, HEATSINK
TEMPERATURE
HEATSINK
RθSA
TA, AMBIENT
TEMPERATURE
FLAT WASHER
SOLDER TERMINAL
NUT
REFERENCE TEMPERATURE
Figure A1. Basic Thermal Resistance Model Showing Thermal to Electrical Analogy for a Semiconductor
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APPENDIX B
MEASUREMENT OF INTERFACE THERMAL RESISTANCE
Measuring the interface thermal resistance RθCS
appears deceptively simple. All that’s apparently needed
is a thermocouple on the semiconductor case, a thermocouple on the heatsink, and a means of applying and
measuring DC power. However, RθCS is proportional to
the amount of contact area between the surfaces and
consequently is affected by surface flatness and finish and
the amount of pressure on the surfaces. The fastening
method may also be a factor. In addition, placement of the
thermocouples can have a significant influence upon the
results. Consequently, values for interface thermal resistance presented by different manufacturers are not in good
agreement. Fastening methods and thermocouple locations are considered in this Appendix.
When fastening the test package in place with screws,
thermal conduction may take place through the screws,
for example, from the flange ear on a TO-3 package
directly to the heatsink. This shunt path yields values
which are artificially low for the insulation material and
dependent upon screw head contact area and screw
material. MIL-I-49456 allows screws to be used in tests
for interface thermal resistance probably because it can be
argued that this is “application oriented.”
Thermalloy takes pains to insulate all possible shunt
conduction paths in order to more accurately evaluate
insulation materials. The ON Semiconductor fixture uses
an insulated clamp arrangement to secure the package
which also does not provide a conduction path.
As described previously, some packages, such as a
TO-220, may be mounted with either a screw through the
tab or a clip bearing on the plastic body. These two
methods often yield different values for interface thermal
resistance. Another discrepancy can occur if the top of the
package is exposed to the ambient air where radiation and
convection can take place. To avoid this, the package
should be covered with insulating foam. It has been
estimated that a 15 to 20% error in RθCS can be incurred
from this source.
Another significant cause for measurement discrepancies is the placement of the thermocouple to measure the
semiconductor case temperature. Consider the TO-220
package shown in Figure B1. The mounting pressure at
one end causes the other end — where the die is located
— to lift off the mounting surface slightly. To improve
contact, ON Semiconductor TO-220 Packages are slightly
concave. Use of a spreader bar under the screw lessens the
lifting, but some is inevitable with a package of this
structure. Three thermocouple locations are shown:
b. The JEDEC location is close to the die on the top
surface of the package base reached through a blind hole
drilled through the molded body. The thermocouple is
swaged in place.
c. The Thermalloy location is on the top portion of the
tab between the molded body and the mounting screw.
The thermocouple is soldered into position.
E.I.A.
DIE
THERMALLOY
ON SEMICONDUCTOR
Figure B1. JEDEC TO-220 Package Mounted to
Heatsink Showing Various Thermocouple Locations
and Lifting Caused by Pressure at One End
Temperatures at the three locations are generally not the
same. Consider the situation depicted in the figure.
Because the only area of direct contact is around the
mounting screw, nearly all the heat travels horizontally
along the tab from the die to the contact area. Consequently, the temperature at the JEDEC location is hotter than at
the Thermalloy location and the ON Semiconductor
location is even hotter. Since junction-to-sink thermal
resistance must be constant for a given test setup, the
calculated junction-to-case thermal resistance values
decrease and case-to-sink values increase as the “case”
temperature thermocouple readings become warmer.
Thus the choice of reference point for the “case”
temperature is quite important.
There are examples where the relationship between the
thermocouple temperatures are different from the previous situation. If a mica washer with grease is installed
between the semiconductor package and the heatsink,
tightening the screw will not bow the package; instead,
the mica will be deformed. The primary heat conduction
path is from the die through the mica to the heatsink. In
this case, a small temperature drop will exist across the
vertical dimension of the package mounting base so that
the thermocouple at the EIA location will be the hottest.
The thermocouple temperature at the Thermalloy location
will be lower but close to the temperature at the EIA
location as the lateral heat flow is generally small. The
ON Semiconductor location will be coolest.
a. The ON Semiconductor location is directly under the
die reached through a hole in the heatsink. The thermocouple is held in place by a spring which forces the
thermocouple into intimate contact with the bottom of the
semi’s case.
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specified junction-to-case values of some of the higher
power semiconductors becoming available, however, the
difference becomes significant and it is important that the
semiconductor manufacturer and equipment manufacturer use the same reference point.
Another EIA method of establishing reference temperatures utilizes a soft copper washer (thermal grease is used)
between the semiconductor package and the heatsink. The
washer is flat to within 1 mil/inch, has a finish better than
63 μ-inch, and has an imbedded thermocouple near its
center. This reference includes the interface resistance
under nearly ideal conditions and is therefore applicationoriented. It is also easy to use but has not become widely
accepted.
A good way to improve confidence in the choice of case
reference point is to also test for junction-to-case thermal
resistance while testing for interface thermal resistance. If
the junction-to-case values remain relatively constant as
insulators are changed, torque varied, etc., then the case
reference point is satisfactory.
The EIA location is chosen to obtain the highest
temperature on the case. It is of significance because
power ratings are supposed to be based on this reference
point. Unfortunately, the placement of the thermocouple
is tedious and leaves the semiconductor in a condition
unfit for sale.
The ON Semiconductor location is chosen to obtain the
highest temperature of the case at a point where,
hopefully, the case is making contact to the heatsink.
Once the special heatsink to accommodate the thermocouple has been fabricated, this method lends itself to
production testing and does not mark the device. However, this location is not easily accessible to the user.
The Thermalloy location is convenient and is often
chosen by equipment manufacturers. However, it also
blemishes the case and may yield results differing up to
1°C/W for a TO-220 package mounted to a heatsink
without thermal grease and no insulator. This error is
small when compared to the thermal resistance of heat
dissipaters often used with this package, since power
dissipation is usually a few watts. When compared to the
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SECTION 8
RELIABILITY AND QUALITY
Edited and Updated
stable. However, for pulses in the microsecond and
millisecond region, the use of steady−state values will not
yield true power capability because the thermal response of
the system has not been taken into account.
Note, however, that semiconductors also have pulse
power limitations which may be considerably lower − or
even greater − than the allowable power as deduced from
thermal response information. For transistors, the second
breakdown portion of the pulsed safe operating area
defines power limits while surge current or power ratings
are given for diodes and thyristors. These additional ratings
must be used in conjunction with the thermal response to
determine power handling capability.
To account for thermal capacity, a time dependent factor
r(t) is applied to the steady−state thermal resistance.
Thermal resistance, at a given time, is called transient
thermal resistance and is given by:
USING TRANSIENT THERMAL RESISTANCE
DATA IN HIGH POWER PULSED THYRISTOR
APPLICATIONS
INTRODUCTION
For a certain amount of dc power dissipated in a
semiconductor, the junction temperature reaches a value
which is determined by the thermal conductivity from the
junction (where the power is dissipated) to the air or heat
sink. When the amount of heat generated in the junction
equals the heat conducted away, a steady−state condition is
reached and the junction temperature can be calculated by
the simple equation:
TJ = PD RθJR + TR
where
(1a)
TJ = junction temperature
TR = temperature at reference point
PD = power dissipated in the junction
RθJR = steady−state thermal resistance from
RθJR = junction to the temperature reference
RθJR = point.
RθJR(t) = r(t) RθJR
The mathematical expression for the transient thermal
resistance has been determined to be extremely complex.
The response is, therefore, plotted from empirical data.
Curves, typical of the results obtained, are shown in
Figure 8.1. These curves show the relative thermal
response of the junction, referenced to the case, resulting
from a step function change in power. Observe that the total
percentage difference is about 10:1 in the short pulse ( t)
region. However, the values of thermal resistance vary over
20:1.
Many ON Semiconductor data sheets have a graph
similar to that of Figure 8.2. It shows not only the thermal
response to a step change in power (the D = 0, or single
pulse curve) but also has other curves which may be used to
obtain an effective r(t) value for a train of repetitive pulses
with different duty cycles. The mechanics of using the
curves to find TJ at the end of the first pulse in the train, or
to find TJ(pk) once steady state conditions have been
achieved, are quite simple and require no background in
the subject. However, problems where the applied power
pulses are either not identical in amplitude or width, or the
duty cycle is not constant, require a more thorough
understanding of the principles illustrated in the body of
this report.
Power ratings of semiconductors are based upon steady−
state conditions, and are determined from equation (1a)
under worst case conditions, i.e.:
PD(max) TJ(max) – TR
RqJR(max)
(2)
(1b)
TJ(max) is normally based upon results of an operating life
test or serious degradation with temperature of an important device characteristic. TR is usually taken as 25°C, and
RθJR can be measured using various techniques. The
reference point may be the semiconductor case, a lead, or
the ambient air, whichever is most appropriate. Should the
reference temperature in a given application exceed the
reference temperature of the specification, PD must be
correspondingly reduced.
Thermal resistance allows the designer to determine
power dissipation under steady state conditions. Steady
state conditions between junction and case are generally
achieved in one to ten seconds while minutes may be
required for junction to ambient temperature to become
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USE OF TRANSIENT THERMAL RESISTANCE DATA
The temperature is desired, a) at the end of the first pulse
b) at the end of a pulse under steady state conditions.
For part (a) use:
Part of the problem in applying thermal response data
stems from the fact that power pulses are seldom rectangular, therefore to use the r(t) curves, an equivalent rectangular model of the actual power pulse must be determined.
Methods of doing this are described near the end of this
note.
Before considering the subject matter in detail, an
example will be given to show the use of the thermal
response data sheet curves. Figure 8.2 is a representative
graph which applies to a 2N5886 transistor.
TJ = r(5 ms) RθJCPD + TC
The term r(5 ms) is read directly from the graph of
Figure 8.2 using the D = 0 curve,
∴ TJ = 0.49 1.17 50 + 75 = 28.5 + 75 = 103.5
The peak junction temperature rise under steady conditions
is found by:
TJ = r(t, D) RθJC PD + TC
r (t) , Transient Thermal Resistance
(Normalized)
Pulse power PD = 50 Watts
Duration t = 5 milliseconds
Period τp = 20 milliseconds
Case temperature, TC = 75°C
Junction to case thermal resistance,
RθJC = 1.17°C/W
D = t/τp = 5/20 − 0.25. A curve for D= 0.25 is not on the
graph; however, values for this duty cycle can be interpolated between the D = 0.2 and D = 0.5 curves. At 5 ms,
read r(t) ≈ 0.59.
TJ = 0.59 1.17 50 + 75 = 34.5 + 75 = 109.5°C
1.0
0.7
0.5
CASE
0.3
1
2
0.2
0.1
0.07
0.05
0.03
0.02
0.01
0.1
1
2
0.2
0.5
1.0
2.0
5.0
10
20
50
t, Time (ms)
100
200
Case 77
Case 77
500
1000
DIE SIZE
(Sq. Mils)
3,600
8,000
2000
5000
10,000
r (t) , Transient Thermal Resistance
(Normalized)
Figure 8.1. Thermal Response, Junction to Case, of Case 77 Types For a Step of Input Power
1.0
0.7
0.5
D = 0.5
0.3
0.2
0.2
0.1
0.07
0.05
0.03
0.02
0.01
0.01
0.1
0.05
0.02
0.01
SINGLE PULSE
0.02
0.05
0.1
0.2
0.5
1.0
2.0
5.0
t, Time (ms)
10
20
50
100
Figure 8.2. Thermal Response Showing the Duty Cycle Family of Curves
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200
500
1000
The average junction temperature increase above
ambient is:
TJ(average) − TC
Pin
= RθJC PD D
= (1.17) (50) (0.25)
= 14.62°C
P2
(a)
Input
Power
(3)
Note that TJ at the end of any power pulse does not equal
the sum of the average temperature rise (14.62°C in the
example) and that due to one pulse (28.5°C in example),
because cooling occurs between the power pulses.
While junction temperature can be easily calculated for a
steady pulse train where all pulses are of the same
amplitude and pulse duration as shown in the previous
example, a simple equation for arbitrary pulse trains with
random variations is impossible to derive. However, since
the heating and cooling response of a semiconductor is
essentially the same, the superposition principle may be
used to solve problems which otherwise defy solution.
Using the principle of superposition each power interval
is considered positive in value, and each cooling interval
negative, lasting from time of application to infinity. By
multiplying the thermal resistance at a particular time by
the magnitude of the power pulse applied, the magnitude of
the junction temperature change at a particular time can be
obtained. The net junction temperature is the algebraic sum
of the terms.
The application of the superposition principle is most
easily seen by studying Figure 8.3.
Figure 8.3(a) illustrates the applied power pulses. Figure 8.3(b) shows these pulses transformed into pulses lasting
from time of application and extending to infinity; at to, P1
starts and extends to infinity; at t1, a pulse (− P1) is considered
to be present and thereby cancels P1 from time t1, and so forth
with the other pulses. The junction temperature changes due
to these imagined positive and negative pulses are shown in
Figure 8.3(c). The actual junction temperature is the algebraic
sum as shown in Figure 8.3(d).
Problems may be solved by applying the superposition
principle exactly as described; the technique is referred to
as Method 1, the pulse−by−pulse method. It yields satisfactory results when the total time of interest is much less than
the time required to achieve steady state conditions, and
must be used when an uncertainty exists in a random pulse
train as to which pulse will cause the highest temperature.
Examples using this method are given in Appendix A
under Method 1.
For uniform trains of repetitive pulses, better answers
result and less work is required by averaging the power
pulses to achieve an average power pulse; the temperature
is calculated at the end of one or two pulses following the
average power pulse. The essence of this method is shown
in Figure 8.6. The duty cycle family of curves shown in
Figure 8.2 and used to solve the example problem is based
on this method; however, the curves may only be used for a
uniform train after steady state conditions are achieved.
Method 2 in Appendix A shows equations for calculating
the temperature at the end of the nth or n + 1 pulse in a
uniform train. Where a duty cycle family of curves is
available, of course, there is no need to use this method.
P1
P4
P3
t0
t1
Pin
t2
t3
t4
t5
t6
t7
Time
P2
(b)
Power
Pulses
Separated
Into
Components
P1
P4
P3
−P3
−P4
−P1
Time
−P2
(c)
TJ
Change
Caused
by
Components
Time
TJ
(d)
Composite
TJ
Time
P PK1 Peak Power
(Watts)
Figure 8.3. Application of Superposition Principle
50
40
P1
30
20
10
0
P3
P2
t0 t1 t2
0
t3
1.0
t4 t5
2.0
t, Time (ms)
3.0
4.0
Figure 8.4. Non−Repetitive Pulse Train (Values Shown
Apply to Example in Appendix)
t
T5
Po
t0 t1
t2 t3
t4 t5
t6 t7
t8 t9
t
2t
(Conditions for numerical examples
Po = 5 Watts
t = 5 ms
t = 20 ms
Figure 8.5. A Train of Equal Repetitive Pulses
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nth
A point to remember is that a high amplitude pulse of a
given amount of energy will produce a higher rise in
junction temperature than will a lower amplitude pulse of
longer duration having the same energy.
n+1
pulse
pulse
Po
Pavg
t
t
ÉÉÉÉÉÉ
ÉÉÉÉÉÉ
ÉÉÉÉÉÉ
ÉÉÉÉÉÉ
t
P1
(a)
Figure 8.6. Model For a Repetitive Equal Pulse Train
P1T1 = A
A
Temperature rise at the end of a pulse in a uniform train
before steady state conditions are achieved is handled by
Method 3 (a or b) in the Appendix. The method is basically
the same as for Method 2, except the average power is
modified by the transient thermal resistance factor at the
time when the average power pulse ends.
A random pulse train is handled by averaging the pulses
applied prior to situations suspected of causing high peak
temperatures and then calculating junction temperature at
the end of the nth or n + 1 pulse. Part c of Method 3 shows
an example of solving for temperature at the end of the 3rd
pulse in a three pulse burst.
T1
PP
PP
0.7 PP
(b)
0.7 PP
0.91 t
0.71 t
t
HANDLING NON−RECTANGULAR PULSES
The thermal response curves, Figure 8.1, are based on a
step change of power; the response will not be the same for
other waveforms. Thus far in this treatment we have
assumed a rectangular shaped pulse. It would be desirable
to be able to obtain the response for any arbitrary
waveform, but the mathematical solution is extremely
unwieldy. The simplest approach is to make a suitable
equivalent rectangular model of the actual power pulse and
use the given thermal response curves; the primary rule to
observe is that the energy of the actual power pulse and the
model are equal.
Experience with various modeling techniques has lead to
the following guidelines:
t
ÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉ
ÉÉÉÉÉÉÉÉÉÉÉ
P1
(c)
P1 (t1 − t0) + P2 (t2 − t1) = A
P2
A
t0
t1
t2
Figure 8.7. Modeling of Power Pulses
As an example, the case of a transistor used in a dc to ac
power converter will be analyzed. The idealized waveforms of collector current, IC, collector to emitter voltage,
VCE, and power dissipation PD, are shown in Figure 8.8.
A model of the power dissipation is shown in
Figure 8.8(d). This switching transient of the model is
made, as was suggested, for a triangular pulse.
For example, TJ at the end of the rise, on, and fall times,
T1, T2 and T3 respectively, will be found.
For a pulse that is nearly rectangular, a pulse model
having an amplitude equal to the peak of the actual pulse,
with the width adjusted so the energies are equal, is a
conservative model. (See Figure 8.7(a)).
Sine wave and triangular power pulses model well with
the amplitude set at 70% of the peak and the width
adjusted to 91% and 71%, respectively, of the baseline
width (as shown on Figure 8.7(b)).
Conditions:
TO−3 package,
RθJC = 0.5°C/W, IC = 60A, VCE(off) = 60 V
TA = 50°C
tf = 80 μs, tr = 20 μs
VCE(sat) = 0.3 V @ 60 A
Frequency = 2 kHz∴τ = 500 μs
Pon = (60) (0.3) = 18 W
Pf = 30 30 = 900 W = Pr
A power pulse having a sin2 shape models as a triangular
waveform.
Power pulses having more complex waveforms could be
modeled by using two or more pulses as shown in
Figure 8.7(c).
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(a)
tf
toff
tr
ton
VCE
Time
t
t
Pavg 0.7 Pr 0.71 r Pon ton 0.7 Pf 0.71 f
t
t
t
(b)
(20)
(150)
(18)
500
500
Collector Current
t
Procedure: Average each pulse over the period using
equation 1−3 (Appendix A, Method 2), i.e.,
IC
Time
(0.7) (900) (0.71) 80
500
17.9 5.4 71.5
(c)
94.8 W
Power Dissipation
(0.7) (900) (0.71)
Collector−Emitter Voltage
Assume that the response curve in Figure 8.1 for a die
area of 58,000 square mils applies. Also, that the device is
mounted on an MS−15 heat sink using Dow Corning
DC340 silicone compound with an air flow of 1.0 lb/min
flowing across the heat−sink. (From MS−15 Data Sheet,
RθCS = 0.1°C/W and RθSA = 0.55°C/W).
PD
Pf
Pr
Pon
t(Time)
From equation 1−4, Method 2A:
T1 = [Pavg + (0.7 Pr − Pavg) r(t1 − to)] RθJC
(d)
PD
0.7 Pf
T1 T2T3
0.7 Pr
0.7 Pf
Pon
At this point it is observed that the thermal response
curves of Figure 8.1 do not extend below 100 μs. Heat
transfer theory for one dimensional heat flow indicates that
the response curve should follow the t law at small times.
Using this as a basis for extending the curve, the response
at 14.2 μs is found to be 0.023.
0.7 tr
0.7 tf
ton
t0 t1
t(Time)
t2 t3
Figure 8.8. Idealized Waveforms of IC, VCE and
PD in a DC to AC Inverter
We then have:
For the final point T3 we have:
T1 = [94.8 + (630 − 94.8).023] (0.5)
T3 = [Pavg − Pavg r(t3 − to) + 0.7 Pr T1 = (107.11)(0.5) = 53.55°C
T3 = r(t3 − to) − 0.7 Pr r(t3 − t1) + Pon For T2 we have, by using superposition:
T3 = r(t3 − t1) − Pon r(t3 − t2)
T2 = [Pavg − Pavg r(t2 − to) + 0.7 Pr T3 = + 0.7 Pf r(t3 − t2)] RθJC
T2 = r(t2 − to) − 0.7 Pr r(t2 − t1) + Pon T3 = [Pavg + (0.7 Pr − Pavg) r(t3 − to) +
T2 = r(t2 − t1)] RθJC
T3 = (Pon − 0.7 Pr) r(t3 − t1) + (0.7 Pf − Pon)
T2 = [Pavg + (0.7 Pr − Pavg) r(t2 − to) +
T3 = T2 = (Pon − 0.7 Pr) r(t2 − t1)] RθJC
r(t3 − t2)] RθJC
T3 = [94.8 + (535.2) r(221 μs) + (−612) r(206.8 μs)
T2 = [94.8 + (630 − 94.8) r(164 μs) + (18 − 630)
T3 = + (612) r(56.8μs)] (0.5)
T2 = r(150 μs)] (0.5)
T3 = [94.8 + (535.2)(0.09) − (612) (0.086) +
T2 = [94.8 + (535.2)(.079) − (612)(.075)] (0.5)
T3 = (612)(0.045)] (0.5)
T2 = [94.8 + 42.3 − 45.9] (0.5)
T3 = [94.8 + 481.7− 52.63 + 27.54] (0.5)
T2 = (91.2)(0.5) = 45.6°C
T3 = (117.88)(0.5) = 58.94°C
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Table 8.1. Several Possible Methods of Solutions
The junction temperature at the end of the rise, on, and
fall times, TJ1, TJ2, and TJ3, is as follows:
1. Junction Temperature Rise Using Pulse−By−Pulse
Method
A. Temperature rise at the end of the nth pulse for pulses
with unequal amplitude, spacing, and duration.
B. Temperature rise at the end of the nth pulse for pulses
with equal amplitude, spacing, and duration.
2. Temperature Rise Using Average Power Concept
Under Steady State Conditions For Pulses Of Equal
Amplitude, Spacing, And Duration
A. At the end of the nth pulse.
B. At the end of the (n + 1) pulse.
3. Temperature Rise Using Average Power Concept
Under Transient Conditions.
A. At the end of the nth pulse for pulses of equal
amplitude, spacing and duration.
B. At the end of the n + 1 pulse for pulses of equal
amplitude, spacing and duration.
C. At the end of the nth pulse for pulses of unequal
amplitude, spacing and duration.
D. At the end of the n + 1 pulse for pulses of unequal
amplitude, spacing and duration.
TJ1 = T1 + TA + RθCA Pavg
RθCA = RθCS = RθSA = 0.1 + 0.55
TJ1 = 53.55 + 50 + (0.65)(94.8) = 165.17°C
TJ2 = T2 + TA + RθCA Pavg
TJ2 = 45.6 + 50 + (0.65)(94.8)
TJ2 = 157.22°C
TJ3 = T3 + TA + RθCA Pavg
TJ3 = 58.94 + 50 + (0.65)(94.8)
TJ3 = 170.56°C
TJ(avg) = Pavg (RθJC + RθCS + RθSA) + TA
TJ(avg) = (94.8)(0.5 + 0.1 + 0.55) + 50
TJ(avg) = (94.8)(1.15) + 50 = 159.02°C
Inspection of the results of the calculations T1, T2, and
T3 reveal that the term of significance in the equations is
the average power. Even with the poor switching times
there was a peak junction temperature of 11.5°C above the
average value. This is a 7% increase which for most
applications could be ignored, especially when switching
times are considerably less. Thus the product of average
power and steady state thermal resistance is the determining factor for junction temperature rise in this application.
METHOD 1A − FINDING TJ AT THE END OF THE Nth
PULSE IN A TRAIN OF UNEQUAL AMPLITUDE,
SPACING, AND DURATION
General Equation:
n
Tn Pi [r(t2n−1 − t2i−2)
i1
− r(tn−1 − t2i−1)]RθJC
&
SUMMARY
This report has explained the concept of transient
thermal resistance and its use. Methods using various
degrees of approximations have been presented to determine the junction temperature rise of a device. Since the
thermal response data shown is a step function response,
modeling of different wave shapes to an equivalent
rectangular pulse of pulses has been discussed.
The concept of a duty cycle family of curves has also
been covered; a concept that can be used to simplify
calculation of the junction temperature rise under a
repetitive pulse train.
(1−1)
where n is the number of pulses and Pi is the peak value
of the ith pulse.
To find temperature at the end of the first three pulses,
Equation 1−1 becomes:
T1 = P1 r(t1) RθJC
(1−1A)
T2 = [P1 r(t3) − P1 r(t3 − t1)
(1−1B)
T2 = + P2 r(t3 − t2)] RθJC
APPENDIX A METHODS OF SOLUTION
T3 = [P1 r(t5) − P1 r(t5 − t1) + P2 r(t5 − t2)
In the examples, a type 2N3647 transistor will be used;
its steady state thermal resistance, RθJC, is 35°C/W and its
value for r(t) is shown in Figure A1.
T3 = − P2 r(t5 − t3) + P3 r(t5 − t4)] RθJC
Example:
Conditions are shown on Figure 4 as:
t0 = 0
t3 = 1.3 ms
P1 = 40 W
P2 = 20 W
t1 = 0.1 ms
t4 = 3.3 ms
P3 = 30 W
t2 = 0.3 ms
t5 = 3.5 ms
Definitions:
P1, P2, P3 ... Pn = power pulses (Watts)
T
(1−1C)
T1, T2, T3 ... Tn = junction to case temperature at
end of P1, P2, P3 ... Pn
Therefore,
t1 − t0 = 0.1 ms
t2 − t1 = 0.2 ms
t3 − t2 = 1 ms
t4 − t3 = 2 ms
t5 − t4 = 0.2 ms
t0, t1, t2, ... tn = times at which a power pulse
begins or ends
r(tn − tk) = transient thermal resistance factor at
end of time interval (tn − tk).
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t3 − t1 = 1.2 ms
t5 − t1 = 3.4 ms
t5 − t2 = 3.2 ms
t5 − t3 = 2.2 ms
Procedure:
For 5 pulses, equation 1−2A is written:
Find r(tn − tk) for preceding time intervals from Figure 8.2,
then substitute into Equations 1−1A, B, and C.
T5 = PD RθJC [r(4 τ + t) − r(4τ) + r(3τ + t)]
T5 = − r(3τ) + r(2τ + t) − r(2τ) + r(τ + t)
T5 = − r(τ) + r(t)]
T1 = P1 r(t1) RθJC = 40 0.05 35 = 70°C
T2 = [P1 r(t3) − P1 r(t3 − t1) + P2 r(t3 − t2)] RθJC
T2 = [40 (0.175) − 40 (0.170) + 20 (0.155)] 35
Example:
T2 = [40 (0.175 − 0.170) + 20 (0.155)] 35
Conditions are shown on Figure 8.5 substituting values
into the preceding expression:
T2 = [0.2 + 3.1] 35 = 115.5°C
T3 = [P1 r(t5) − P1 r(t5 − t1) + P2 r(t5 − t2)
T5 = (5) (35) [r(4.20 + 5) − r(4.20) + r(3.20 + 5)
T5 = + r(3.20) + r(2.20 + 5) − r(2.20) + r(20 + 5)
T5 = − r(20) + r(5)]
T5 = (5) (35) [0.6 − 0.76 + 0.73 − 0.72 + 0.68
T5 = − 0.66 + 0.59 − 0.55 + 0.33] − (5)(35)(0.40)
T5 = 70.0°C
T3 = − P2 r(t5 − t3) + P3 r(t5 − t4)] θJC
T3 = [40 (0.28) − 40 (0.277) + 20 (0.275) − 20 (0.227)
T3 = + 30 (0.07)] 35
T3 = [40 (0.28 − 0.277) + 20 (0.275 − 0.227)
T3 = + 30 (0.07)] 35
T3 = [0.12 + 0.96 + 2.1]{ 35 = 3.18 35 = 111.3°C
Note that the solution involves the difference between
terms nearly identical in value. Greater accuracy will be
obtained with long or repetitive pulse trains using the
technique of an average power pulse as used in Methods 2
and 3.
Note, by inspecting the last bracketed term in the
equations above that very little residual temperature is left
from the first pulse at the end of the second and third pulse.
Also note that the second pulse gave the highest value of
junction temperature, a fact not so obvious from inspection
of the figure. However, considerable residual temperature
from the second pulse was present at the end of the third
pulse.
METHOD 2 − AVERAGE POWER METHOD, STEADY
STATE CONDITION
The essence of this method is shown in Figure 8.6.
Pulses previous to the nth pulse are averaged. Temperature
due to the nth or n + 1 pulse is then calculated and
combined properly with the average temperature.
Assuming the pulse train has been applied for a period of
time (long enough for steady state conditions to be
established), we can average the power applied as:
METHOD 1B − FINDING TJ AT THE END OF THE Nth
PULSE IN A TRAIN OF EQUAL AMPLITUDE, SPACING,
AND DURATION
The general equation for a train of equal repetitive pulses
can be derived from Equation 1−1. Pi = PD, ti = t, and the
spacing between leading edges or trailing edges of adjacent
pulses is τ.
Pavg PD tt
General Equation:
n
Tn = PDRθJC
& r[(n − i) τ +
METHOD 2A − FINDING TEMPERATURE AT THE END
OF THE Nth PULSE
(1−2)
i1 t]
− r[(n − i) τ]
Applicable Equation:
Tn = [Pavg + (PD − Pavg) r(t)] RθJC
Expanding:
Tn = PD RθJC r[(n − 1) τ + t] − r[(n − 1) τ]
Tn = + r[(n − 2) τ + t) − r[(n − 2) τ] + r[(n − 3)
Tn = τ + t] − r[(n − 3) τ] + . . . + r[(n − i) τ + t]
Tn = − r[(n − i) τ] . . . . . + r(t)]
(1−3)
(1−4)
or, by substituting Equation 1−3 into 1−4,
Tn tt 1– tt r(t) PD RqJC
(1−2A)
(1−5)
The result of this equation will be conservative as it adds
a temperature increase due to the pulse (PD − Pavg) to the
average temperature. The cooling between pulses has not
been accurately accounted for; i.e., TJ must actually be less
than TJ(avg) when the nth pulse is applied.
{Relative
amounts of temperature residual from P1, P2, and
P3 respectively are indicated by the terms in brackets.
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Example: Find Tn for conditions of Figure 8.5.
Procedure: Find Pavg from equation (1−3) and
substitute values in equation (1−4) or
(1−5).
METHOD 3 − AVERAGE POWER METHOD,
TRANSIENT CONDITIONS
The idea of using average power can also be used in the
transient condition for a train of repetitive pulses. The
previously developed equations are used but Pavg must be
modified by the thermal response factor at time t(2n − 1).
Tn = [(1.25) + (5.0 − 1.25)(0.33)] (35)
Tn = 43.7 + 43.2 = 86.9°C
METHOD 3A − FINDING TEMPERATURE AT THE END
OF THE Nth PULSE FOR PULSES OF EQUAL
AMPLITUDE, SPACING AND DURATION
METHOD 2B − FINDING TEMPERATURE AT THE END
OF THE N + 1 PULSE
Applicable Equation:
Applicable Equation:
Tn + 1 = [Pavg + (PD − Pavg) r(t + τ)
Tn + 1 + PD r(t) − PD r(τ)] RθJC
t
t
t 1– t r(t t)
PD RθJC
(1−8)
Conditions: (See Figure 8.5)
Procedure: At the end of the 5th pulse
(See Figure 8.7) . . .
or, by substituting equation 1−3 into 1−6,
Tn + 1 =
Tn tt r t(2n–1) 1 – tt r(t)
(1−6)
T5 = [5/20 r(85) + (1 − 5/20)r(5)] (5)(35)
T5 = [(0.25)(0765) + (0.75)(0.33)] (175)
T5 = 77°C
(1−7)
r(t) r(t) PDRθJC
This value is a little higher than the one calculated by
summing the results of all pulses; indeed it should be,
because no cooling time was allowed between Pavg and the
nth pulse. The method whereby temperature was calculated
at the n + 1 pulse could be used for greater accuracy.
Example: Find Tn for conditions of Figure 8.5.
Procedure: Find Pavg from equation (1−3) and
substitute into equation (1−6) or (1−7).
Tn + 1 = [(1.25) + (5 − 1.25)(0.59) + (5)(0.33)
Tn + 1 − (5)(0.56)] (35) = 80.9°C
METHOD 3B − FINDING TEMPERATURE AT THE END
OF THE N + 1 PULSE FOR PULSES OF EQUAL
AMPLITUDE, SPACING AND DURATION
Equation (1−6) gives a lower and more accurate value for
temperature than equation (1−4). However, it too gives a
higher value than the true TJ at the end of the n + 1th pulse.
The error occurs because the implied value for TJ at the end
of the nth pulse, as was pointed out, is somewhat high.
Adding additional pulses will improve the accuracy of the
calculation up to the point where terms of nearly equal
value are being subtracted, as shown in the examples using
the pulse by pulse method. In practice, however, use of this
method has been found to yield reasonable design values
and is the method used to determine the duty cycle of
family of curves − e.g., Figure 8.2.
Note that the calculated temperature of 80.9°C is 10.9°C
higher than the result of example 1B, where the temperature was found at the end of the 5th pulse. Since the thermal
response curve indicates thermal equilibrium in 1 second,
50 pulses occurring 20 milliseconds apart will be required
to achieve stable average and peak temperatures; therefore,
steady state conditions were not achieved at the end of the
5th pulse.
Applicable Equation:
Tn + 1 =
t
t
t r(t2n–1) 1 – t
r(t t) r(t) r(t) PD RθJC
Example: Conditions as shown on Figure 8.5. Find
temperature at the end of the 5th pulse.
For n + 1 = 5, n = 4, t2n−1 = t7 = 65 ms,
5 r(65 ms) 1 – 5 r(25 ms)
20
20
T5 =
r(5 ms) r(20 ms) (5)(35)
T5 = [(0.25)(0.73) + (0.75)(0.59) + 0.33 − 0.55](5)(35)
T5 = 70.8°C
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(1−9)
The answer agrees quite well with the answer of Method
1B where the pulse−by−pulse method was used for a
repetitive train.
This result is high because in the actual case considerable
cooling time occurred between P2 and P3 which allowed TJ
to become very close to TC. Better accuracy is obtained
when several pulses are present by using equation 1−10 in
order to calculate TJ − tC at the end of the nth + 1 pulse. This
technique provides a conservative quick answer if it is easy
to determine which pulse in the train will cause maximum
junction temperature.
METHOD 3C − FINDING TJ AT THE END OF THE Nth
PULSE IN A RANDOM TRAIN
The technique of using average power does not limit
itself to a train of repetitive pulses. It can be used also
where the pulses are of unequal magnitude and duration.
Since the method yields a conservative value of junction
temperature rise it is a relatively simple way to achieve a
first approximation. For random pulses, equations 1−4
through 1−7 can be modified. It is necessary to multiply
Pavg by the thermal response factor at time t(2n − 1). Pavg is
determined by averaging the power pulses from time of
application to the time when the last pulse starts.
METHOD 3D − FINDING TEMPERATURE AT THE END
OF THE N + 1 PULSE IN A RANDOM TRAIN
The method is similar to 3C and the procedure is
identical. Pavg is calculated from Equation 1−10 modified
by r(t2n − 1) and substituted into equation 1−6, i.e.,
Applicable Equations:
n
General: Pavg =
&
i1
t(2i−1)−t(2i−2)
Pi
t(2n)−t(2i−2)
Tn + 1 = [Pavg r(t2n−1) + (PD − Pave) r(t2n−1 −
Tn + 1 = t2n−2) + PD r(t2n+1 − t2n) − PD r(t2n+1
Tn + 1 = − t2n−1)] RθJC
(1−10)
For 3 Pulses:
Pavg = P1
t1 − t0
+ P2
t4 − t0
t3 − t2
t4 − t2
The previous example cannot be worked out for the n + 1
pulse because only 3 pulses are present.
(1−11)
Example:
Conditions are shown on Figure 8.4 (refer to
Method 1A).
Procedure: Find Pavg from equation 1−3 and the junction
temperature rise from equation 1−4.
Conditions: Figure 8.4
Table 8.2. Summary Of Numerical Solution For The
Repetitive Pulse Train Of Figure 5
Temperature Obtained, °C
r (t) , Transient Thermal Resistance
(Normalized)
Pavg = 40 0.1 20 1 1.21 6.67
3.3
3
= 7.88 Watts
T3 = [Pavg r(t5) + (P3 − Pavg) r(t5 − t4)] RθJC
= [7.88 (0.28) + (30 − 7.88) 0.07] 35
= [2.21 + 1.56] 35 = 132°C
Temperature
Desired
Pulse by
Pulse
Average Power Average Power
Nth Pulse
N + 1 Pulse
At End of
5th Pulse
70.0 (1B)
77 (3A)
70.8 (3B)
Steady State
Peak
−
86.9 (2A)
80.9 (2B)
Note: Number in parenthesis is method used.
1.0
0.7
0.5
0.3
0.2
0.1
0.07
0.05
0.03
0.02
0.01
0.01
0.02
0.05
0.1
0.2
0.5
1.0
2.0
5.0
t, Time (ms)
10
20
50
Figure 8.9. 2N3467 Transient Thermal Response
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100
200
500
1000
r (t) , Transient Thermal Resistance
(Normalized)
1.0
0.7
0.5
0.3
0.2
0.1
0.07
0.05
0.03
0.02
0.01
0.1
Case 221
Case 77
1
1
2
2
0.2
0.5
1.0
2.0
5.0
10
20
50
100
200
DIE SIZE
(Sq. Mils)
DEVICE TYPE
8,100
16,900
MCR106−6
2N6344
500
1000
2000
5000
10,000
1000
2000
5000
10,000
t, Time (ms)
r (t) , Transient Thermal Resistance
(Normalized)
Figure 8.10. Case 77 and TO−220 Thermal Response
1.0
0.7
0.5
0.3
0.2
0.1
0.07
0.05
0.03
0.02
0.01
0.1
0.2
0.5
1.0
2.0
5.0
10
20
50
100
200
500
t, Time (ms)
Figure 8.11. TO−92 Thermal Response, Applies to All Commonly Used Die
Given:
Purchase = 100,000 components @ 15¢ each
Assumptions: Line Fallout = 0.1%
Assumptions: Warranty Failures = 0.01%
As the price of semiconductor devices decreases, reliability and quality have become increasingly important in
selecting a vendor. In many cases these considerations even
outweigh price, delivery and service.
The reason is that the cost of device fallout and warranty
repairs can easily equal or exceed the original cost of the
devices. Consider the example shown in Figure 8.12.
Although the case is simplistic, the prices and costs are
realistic by today’s standards. In this case, the cost of
failures raised the device cost from 15 cents to 21 cents, an
increase of 40%. Clearly, then, investing in quality and
reliability can pay big dividends.
With nearly three decades of experience as a major
semiconductor supplier, ON Semiconductor is one of the
largest manufacturers of discrete semiconductors in the
world today. Since semiconductor prices are strongly
influenced by manufacturing volume, this leadership has
permitted ON Semiconductor to be strongly competitive in
the marketplace while making massive investments in
equipment, processes and procedures to guarantee that the
company’s after−purchase costs will be among the lowest
in the industry.
Components Cost =100,000 15¢ = $15,000
Line Fallout Cost =
100 $40 = 4,000
@ $40 per repair
Warranty Cost =
10 $200 = 2,000
@ $200 per repair
$21,000
Adjusted Cost
Per Component = $21,000 100,000 = 21¢
Definitions:
Line Fall out = Module or subassembly failure
requiring troubleshooting, parts
replacement and retesting
Warranty Failure = System field failure requiring in warranty repair
Figure 8.12. Component Costs to the User
(Including Line Fallout and Warranty Costs)
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RELIABILITY MECHANICS
Quality and reliability are two essential elements in order
for a semiconductor company to be successful in the
marketplace today. Quality and reliability are interrelated
because reliability is quality extended over the expected
life of the product.
Quality is the assurance that a product will fulfill
customers’ expectations.
Reliability is the probability that a product will perform
its intended function satisfactorily for a prescribed life
under certain stated conditions.
The quality and reliability of ON Semiconductor thyristors are achieved with a four step program:
Since reliability evaluations usually involve only samples of an entire population of devices, the concept of the
central limit theorem applies and a failure rate is calculated
using the λ2 distribution through the equation:
2
λ ≤ l (a, 2r 2)
2 nt
λ2 = chi squared distribution
where a 100 – cl
100
λ
cl
r
n
t
1. Thoroughly tested designs and materials
2. Stringent in−process controls and inspections
3. Process average testing along with 100% quality assurance redundant testing
4. Reliability verifications through audits and reliability
studies
=
=
=
=
=
Failure rate
Confidence limit in percent
Number of rejects
Number of devices
Duration of tests
The confidence limit is the degree of conservatism
desired in the calculation. The central limit theorem states
that the values of any sample of units out of a large
population will produce a normal distribution. A 50%
confidence limit is termed the best estimate, and is the
mean of this distribution. A 90% confidence limit is a very
conservative value and results in a higher λ which
represents the point at which 90% of the area of the
distribution is to the left of that value (Figure 8.14).
ESSENTIALS OF RELIABILITY
FREQUENCY
Paramount in the mind of every semiconductor user is
the question of device performance versus time. After the
applicability of a particular device has been established, its
effectiveness depends on the length of trouble free service
it can offer. The reliability of a device is exactly that — an
expression of how well it will serve the customer.
Reliability can be redefined as the probability of failure
free performance, under a given manufacturer’s specifications, for a given period of time. The failure rate of
semiconductors in general, when plotted versus a long
period of time, exhibit what has been called the “bath tub
curve” (Figure 8.13).
50% CL
X
90% CL
l, FAILURE RATE
Figure 8.14. Confidence Limits and the Distribution
of Sample Failure Rates
RANDOM FAILURE
MECHANISM
WEAROUT
PHENOMENON
The term (2r + 2) is called the degrees of freedom and is
an expression of the number of rejects in a form suitable to
λ2 tables. The number of rejects is a critical factor since the
definition of rejects often differs between manufacturers.
Due to the increasing chance of a test not being representative of the entire population as sample size and test time are
decreased, the λ2 calculation produces surprisingly high
values of λ for short test durations even though the true
long term failure rate may be quite low. For this reason
relatively large amounts of data must be gathered to
demonstrate the real long term failure rate. Since this
would require years of testing on thousands of devices,
methods of accelerated testing have been developed.
FAILURE RATE
INFANT
MORTALITY
Figure 8.13. Failure Rate of Semiconductor
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228
parameters again after marking the device to further reduce
any mixing problems associated with the first test. Prior to
shipping, the parts are again sampled, tested to a tight
sampling plan by our Quality Assurance department, and
finally our outgoing final inspection checks for correct
paperwork, mixed product, visual and mechanical inspections prior to packaging to the customers.
Years of semiconductor device testing have shown that
temperature will accelerate failures and that this behavior
fits the form of the Arrhenius equation:
R(t) = Ro(t)e−o/KT
Where R(t) = reaction rate as a function of time and
temperature
Ro = A constant
t = Time
T = Absolute temperature, °Kelvin (°C + 273°)
o = Activation energy in electron volts (ev)
K = Boltzman’s constant = 8.62 10−5 ev/°K
AVERAGE OUTGOING QUALITY (AOQ)
AOQ = Process Average Probability of Acceptance 106 (PPM)
Process Average This equation can also be put in the form:
AF = Acceleration factor
T2 = User temperature
T1 = Actual test temperature
No. of Reject Devices
No. of Devices Tested
Probability of Acceptance (1–
No. of Lots Rejected
)
No. of Lots Tested
106 = To Convert to Parts Per Million
AOQ The Arrhenius equation states that reaction rate increases
exponentially with the temperature. This produces a
straight line when plotted on log−linear paper with a slope
expressed by o. o may be physically interpreted as the
energy threshold of a particular reaction or failure mechanism. The overall activation energy exhibited by
ON Semiconductor thyristors is 1 ev.
(1 –
No. of Reject Devices
No. of Devices Tested
No. of Lots Rejected
) 106(PPM)
No. of Lots Tested
THYRISTOR RELIABILITY
The reliability data described herein applies to
ON Semiconductor’s extensive offering of thyristor products for low and medium current applications. The line
includes not only the pervasive Silicon Controlled Rectifiers (SCRs) and TRIACs, but also a variety of Programmable Unijunction Transistors (PUTs), SIDACs and other
associated devices used for SCR and TRIAC triggering
purposes. Moreover, these devices are available in different
package styles with overlapping current ranges to provide
an integral chip−and−package structure that yields lowest
cost, consistent with the overriding consideration of high
reliability.
Some of the various packages and the range of electrical
specifications associated with the resultant products are
shown in Figure 8.15.
To evaluate the reliability of these structures, production
line samples from each type of package are being subjected
to a battery of accelerated reliability tests deliberately
designed to induce long−term failure. Though the tests are
being conducted on a continuing basis, the results so far are
both meaningful and impressive. They are detailed on the
following pages in the hope that they will provide for the
readers a greater awareness of the potential for thyristors in
their individual application.
RELIABILITY QUALIFICATIONS/EVALUATIONS
OUTLINE:
Some of the functions of ON Semiconductor Reliability
and Quality Assurance Engineering are to evaluate new
products for introduction, process changes (whether minor
or major), and product line updates to verify the integrity
and reliability of conformance, thereby ensuring satisfactory performance in the field. The reliability evaluations may
be subjected to a series of extensive reliability testing, such
as in the tests performed section, or special tests, depending
on the nature of the qualification requirement.
AVERAGE OUTGOING QUALITY (AOQ)
With the industry trend to average outgoing qualities
(AOQ) of less than 100 PPM, the role of device final test,
and final outgoing quality assurance have become a key
ingredient to success. At ON Semiconductor, all parts are
100% tested to process average limits then the yields are
monitored closely by product engineers, and abnormal
areas of fallout are held for engineering investigation.
ON Semiconductor also 100% redundant tests all dc
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These improvements are directed towards long−term
reliability in the most strenuous applications and the most
adverse environments.
TO−92
Case 029/TO−226AA
Devices Available:
SCRs, TRIACs, PUTs
Current Range: to 0.8 A
Voltage Range: 30 to 600 V
DIE GLASSIVATION
All ON Semiconductor thyristor die are glass−sealed
with an ON Semiconductor patented passivation process
making the sensitive junctions impervious to moisture and
impurity penetration. This imparts to low−cost plastic
devices the same freedom from external contamination
formerly associated only with hermetically sealed metal
packages. Thus, metal encapsulation is required primarily
for higher current devices that would normally exceed the
power−dissipation capabilities of plastic packages — or for
applications that specify the hermetic package.
TO−225AA
Case 077/TO−126
Devices Available:
SCRs, TRIACs
Current Range: to 4 A
Voltage Range: 200 to 600 V
VOID−FREE PLASTIC ENCAPSULATION
A fifth generation plastic package material, combined
with improved copper piece−part designs, maximize package integrity during thermal stresses. The void−free
encapsulation process imparts to the plastic package a
mechanical reliability (ability to withstand shock and
vibration) even beyond that of metal packaged devices.
Case 267/Axial Lead
(Surmetic 50)
Devices Available:
SIDAC
Voltage Range: 120 to 240 V
IN−PROCESS CONTROLS AND INSPECTIONS
INCOMING INSPECTIONS
Apparently routine procedures, inspection of incoming
parts and materials, are actually among the most critical
segments of the quality and reliability assurance program.
That’s because small deviations from materials specifications can traverse the entire production cycle before being
detected by outgoing Quality Control, and, if undetected,
could affect long−term reliability. At ON Semiconductor,
piece−part control involves the services of three separate
laboratories . . . Radiology, Electron Optics and Product
Analysis. All three are utilized to insure product integrity:
Raw Wafer Quality, in terms of defects, orientation,
flatness and resistivity;
Physical Dimensions, to tightly specified tolerances;
Metal Hardness, to highly controlled limits;
Gaseous Purity and Doping Level;
Mold Compounds, for void−free plastic encapsulation.
TO−220AB
Case 221A
Devices Available:
SCRs, TRIACs
Current Range: to 55 A
Voltage Range: 50 to 800 V
Figure 8.15. Examples of ON Semiconductor’s
Thyristor Packages
THYRISTOR CONSTRUCTION THROUGH A
TIME TESTED DESIGN AND ADVANCED
PROCESSING METHODS
IN−PROCESS INSPECTIONS
As illustrated in Figure 8.16, every major manufacturing
step is followed by an appropriate in−process QA inspection. Quality control in wafer processing, assembly and
final test impart to ON Semiconductor standard thyristors a
reliability level that easily exceeds most industrial, consumer and military requirements . . . built−in quality
assurance aimed at insuring failure−free shipments of
ON Semiconductor products.
A pioneer in discrete semiconductor components
and one of the world’s largest suppliers thereof,
ON Semiconductor has pyramided continual process and
material improvements into thyristor products whose
inherent reliability meets the most critical requirements of
the market.
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230
RELIABILITY AUDITS
ON Semiconductor’s 100% electrical parametric test does
— by eliminating all devices that do not conform to the
specified characteristics. Additional parametric tests, on a
sampling basis, provide data for continued improvement of
product quality. And to help insure safe arrival after
shipment, antistatic handling and packaging methods are
employed to assure that the product quality that has been
built in stays that way.
From rigid incoming inspection of piece parts and
materials to stringent outgoing quality verification, assembly and process controls encompass an elaborate system of
test and inspection stations that ensure step−by−step
adherence to a prescribed procedure designed to yield a
high standard of quality.
Reliability audits are performed following assembly.
Reliability audits are used to detect process shifts which
can have an adverse effect on long−term reliability.
Extreme stress testing on a real−time basis, for each
product run, uncovers process abnormalities that may have
escaped the stringent in−process controls. Typical tests
include HTRB/FB (high−temperature reverse bias and
forward bias) storage life and temperature cycling. When
abnormalities are detected, steps are taken to correct the
process.
OUTGOING QC
The most stringent in−process controls do not guarantee
strict adherence to tight electrical specifications.
IN−
COMING
INSP.
WAFER &
CHEMICALS
DIFFUSION,
MOAT ETCH,
PHOTOGLASS
INC.
INSP.
FORM &
CLEAN
PC. PARTS
QA INSPECTION
DIE BOND
INJECTION MOLD
& DEFLASH PLASTIC,
CLEAN & SOLDER
DIP LEADS,
CURE PLASTIC
RELIA−
BILITY
AUDITS
METALLIZATION,
100% DIE ELECT, TESTS
SCRIBE & BREAK
RESIS−
TIVITY
INSPECTION
LEAD
ATTACHMENT
QA
INSPECTION
100% ELECT.
SELECTION, 100%
BIN SPECIFICATION
TEST, 100% QA
INSPECTION
LASER MARKING
FINAL
VISUAL
&
MECHANICAL
ELEC.
& VISUAL
INSPECTION
OUTGOING
QC
SAMPLING
QA
INSPECTION
100%
ANTISTATIC
HANDLING/PACKAGING
SHIPPING
Figure 8.16. In−Process Quality Assurance Inspection Points for Thyristors
RELIABILITY TESTS
But thorough testing, in conjunction with rigorous statistical analysis, is the next−best thing. The series of torture
tests described in this document instills a high confidence
level regarding thyristor reliability. The tests are conducted
at maximum device ratings and are designed to deliberately
stress the devices in their most susceptible failure models.
The severity of the tests compresses into a relatively short
Only actual use of millions of devices, under a thousand
different operating conditions, can conclusively establish
the reliability of devices under the extremes of time,
temperature, humidity, shock, vibration and the myriads of
other adverse variables likely to be encountered in practice.
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231
Table 8.4. Leakage−Current Drift
after 1000 Hours HTRB
test cycle the equivalent of the stresses encountered during
years of operation under more normal conditions. The
results not only indicate the degree of reliability in terms of
anticipated failures; they trigger subsequent investigations
into failure modes and failure mechanisms that serve as the
basis of continual improvements. And they represent a
clear−cut endorsement that, for ON Semiconductor thyristors, low−cost and high quality are compatible attributes.
VDRM = 400 V
TA = 100°C
BLOCKING LIFE TEST
This test is used as an indicator of long−term operating
reliability and overall junction stability (quality). All
semiconductor junctions exhibit some leakage current
under reverse−bias conditions. Thyristors, in addition,
exhibit leakage current under forward−bias conditions in
the off state. As a normal property of semiconductors, this
junction leakage current increases proportionally with
temperature in a very predictable fashion.
Leakage current can also change as a function of time —
particularly under high−temperature operation. Moreover,
this undesirable “drift” can produce catastrophic failures
when devices are operated at, or in excess of, rated
temperature limits for prolonged periods.
The blocking life test operates representative numbers of
devices at rated (high) temperature and reverse−bias
voltage limits to define device quality (as measured by
leakage drifts) and reliability (as indicated by the number
of catastrophic failures*). The results of these tests are
shown in Table 8.3. Table 8.4 shows leakage−current drift
after 1000 hours HTRB.
−40 μA
Case
Sample Duration
Size
(Hours)
+20 μA
0
+40 μA
Leakage Shift from Initial Value
The favorable blocking−life−test drift results shown here are attributed to
ON Semiconductor’s unique “glassivated junction” process which imparts a
high degree of stability to the devices.
HIGH TEMPERATURE STORAGE LIFE TEST
This test consists of placing devices in a high−temperature chamber. Devices are tested electrically prior to
exposure to the high temperature, at various time intervals
during the test, and at the completion of testing. Electrical
readout results indicate the stability of the devices, their
potential to withstand high temperatures, and the internal
manufacturing integrity of the package. Readouts at the
various intervals offer information as to the time period in
which failures occur. Although devices are not exposed to
such extreme high temperatures in the field, the purpose of
this test is to accelerate any failure mechanisms that could
occur during long periods at actual storage temperatures.
Results of this test are shown in Table 8.5.
Table 8.3. Blocking Life Test
High Temperature Reverse Bias (HTRB)
and High Temperature Forward Bias (HTFB)
Test
Conditions
TA
@ Rated
Voltage
−20 μA
Table 8.5. High Temperature Storage Life
Total
Device
Hours
Catastrophic
Failures*
Case
Test
Conditions
Sample Duration
Size
(Hours)
Total
Device
Hours
Catastrophic
Failures*
1,500,000
0
1000
1000
1,000,000
1
10002000
400
100°C
Case 029/TO−226AA
(TO−92)
TA = 150°C
Case 029/TO−226AA
(TO−92)
550,000
0
1000
1000
1,000,000
0
10002000
350
110°C
Case 077/TO−225AA
(TO−126)
**
Case 077/TO−225AA
(TO−126)
Case 221A/TO−220
1000
300
300,000
0
Case 221A/TO−220AB
100°C
1000
1000
1,000,000
0
1000
100
100,000
0
Case 267/Axial Lead
(Surmetic 50)
125°C
150
1000
150,000
0
Case 267/Axial Lead
(Surmetic 50)
* Failures are at maximum rated values. The severe nature of these tests
is normally not seen under actual conditions.
** Same for all.
* Failures are at maximum rated values. The severe nature of these tests
is normally not seen under actual conditions.
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STRESS TESTING — POWER CYCLING AND
THERMAL SHOCK
THERMAL SHOCK
CONDITIONS BEYOND THE NORM
POWER CYCLING TEST
Excesses in temperature not only cause variations in
electrical characteristics, they can raise havoc with the
mechanical system. Under temperature extremes, contraction and expansion of the chip and package can cause
physical dislocations of mechanical interfaces and induce
catastrophic failure.
To evaluate the integrity of ON Semiconductor thyristors
under the most adverse temperature conditions, they are
subjected to thermal shock testing.
How do the devices hold up when they are repeatedly
cycled from the off state to the on state and back to the off
state under conditions that force them to maximum rated
junction temperature during each cycle? The Power
Cycling Test was devised to provide the answers.
In this test, devices are subjected to intermittent operating file (IOL), on−state power until the junction temperature (TJ) has increased to 100°C. The devices are then
turned off and TJ decreases to near ambient, at which time
the cycle is repeated.
This test is important to determine the integrity of the chip
and lead frame assembly since it repeatedly stresses the
devices. It is unlikely that these worst−case conditions would
be continuously encountered in actual use. Any reduction in
TJ results in an exponential increase in operating longevity.
Table 8.6 shows the results of IOL testing.
AIR−TO−AIR (TEMPERATURE CYCLING)
This thermal shock test is conducted to determine the
ability of the devices to withstand exposure to extreme high
and low temperature environments and to the shock of
alternate exposures to the temperature extremes. Results of
this test are shown in Table 8.6.
Table 8.6. Air−to−Air
Case
Test Conditions
Sample
Size
Number
of cycles
Total
Device
Cycles
Catastrophic
Failures*
Case 029/TO−226AA (TO−92)
−40°C or −65°C
900
400
360,000
0
Case 077/TO−225AA (TO−126)
to +150°C
500
400
200,000
0
400
400
160,000
0
100
400
40,000
0
Dwell—15 minutes at each extreme
Case 221A/TO−220
Case 267/Axial Lead (Surmetic 50)
Immediate Transfer
* Failures are at maximum rated values. The severe nature of these tests is normally not seen under actual conditions.
ENVIRONMENTAL TESTING
the use of a unique junction “glassivation” process and
selection of package materials. The resistance to moisture−
related failures is indicated by the tests described here.
MOISTURE TESTS
Humidity has been a traditional enemy of semiconductors, particularly plastic packaged devices. Most moisture−
related degradations result, directly or indirectly, from
penetration of moisture vapor through passivating materials, and from surface corrosion. At ON Semiconductor, this
erstwhile problem has been effectively controlled through
BIASED HUMIDITY TEST
This test was devised to determine the resistance of
component parts and constituent materials to the combined
deteriorative effects of prolonged operation in a high−temperature/high−humidity environment. H3TRB test results
are shown in Table 8.7.
Table 8.7. Biased Humidity Test
High Humidity, High Temperature, Reverse Bias (H3TRB)
Case
Test Conditions
Sample
Size
Duration
Hours
Total
Device
Cycles
Catastrophic
Failures*
Case 029/TO−226AA
(TO−92)
Relative Humidity 85%
TA = 85°C
400
500−1000
300,000
0
Case 077/TO−225AA
Reverse Voltage−Rated
or 200 V Maximum
200
500−1000
150,000
0
100
500−1000
75,000
0
30
1000
30,000
0
Case 221A/TO−220
Case 267/Axial Lead (Surmetic 50)
* Failures are at maximum rated values. The severe nature of these tests is normally not seen under actual conditions.
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SECTION 9
APPENDICES
APPENDIX I
USING THE TWO TRANSISTOR ANALYSIS
Equation (3) relates IA to IG, and note that as α1 + α2 = 1,
IA goes to infinity. IA can be put in terms of IK and α’s as
follows:
DEFINITIONS:
IC Collector current
IB Base current
ICS Collector leakage current
(saturation component)
IA Anode current
IK Cathode current
α Current amplification factor
IG Gate current
IB1 = IC2
Combining equations (1) and (2):
IA The subscript “i” indicates the
appropriate transistor.
ICS1 ICS2
I
1 – a 1 – ( K) a 2
IA
IA — ∞ if denominator approaches zero, i.e., if
1 – a1
IK
a2
IA
Note that just prior to turn−on there is a majority carrier
build−up in the P2 “base.” If the gate bias is small there will
actually be hole current flowing out from P2 into the gate
circuit so that IG is negative, IK = IA + IG is less than IA so:
(see Figure 3.2 for the directions of current components)
FOR TRANSISTOR #1:
IC1 = α1 IA + ICSI
and
IK
< 1 which corresponds to α1 + α2 > 1
IA
IB1 = IA − IC1
Combining these equations,
IB1 = (1 − α1) IA − ICS1
A
(1)
IA
P1
DEVICE #1
IB1
IC2
N1
P2
LIKEWISE, FOR TRANSISTOR #2
IC2 = α2IK + ICS2
G
(2)
IG
IB1 = IC2
and by combining Equations (1) and
(2) and substituting IK = IA + IG, it
is found that
a I ICS1 ICS2
IA 2 G
1 – a1 – a2
N1
IC1
N2
IB2
DEVICE #2
P2
IK
K
Figure 9.1. Schematic Diagram of the Two Transistor
Model of a Thyristor
(3)
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APPENDIX II
CHARGE AND PULSE WIDTH
Assume life time at the temperature range of operation
increases as some power of temperature
In the region of large pulse widths using current
triggering, where transit time effects are not a factor, we
can consider the input gate charge for triggering, Qin, as
consisting of three components:
1. Triggering charge Qtr, assumed to be constant.
2. Charge lost in recombination, Qr, during current
regeneration prior to turn−on.
3. Charge drained, Qdr, which is by−passed through the
built−in gate cathode shunt resistance (the presence of
this shunting resistance is required to increase the dv/dt
capability of the device).
Mathematically, we have
Qin = Qtr + Qdr + Qr = IGτ
τ1 = KTm
where K and m are positive real numbers. Combining
Equations (4) and (5), we can get the slope of Qin with
respect to temperature to be
slope Qr = Qin (1 −
dQin
exp.t
t1
V
– m(Qtr GC t) t
t1
T
dT
Rs
(6)
In reality, Qtr is not independent of temperature, in which
case the Equation (6) must be modified by adding an
additional term to become:
(1)
Qr is assumed to be proportional to Qin; to be exact,
exp−τ/τ1)
(5)
exp.t
t1 dQtr
V
slope – m(Qtr GC t) t
expt
t1 (7)
t1
Rs
T
dT
(2)
where IG = gate current,
τ = pulse width of gate current,
τ1 = effective life time of minority carriers in the
bases
Physically, not only does Qtr decrease with temperature
so that dQtr/dT is a negative number, but also |dQtr/dTI
decreased with temperature as does |dα/dTI in the temperature range of interest.
The voltage across the gate to cathode P−N junction during
forward bias is given by VGK (usually 0.6 V for silicon).*
The gate shunt resistance is Rs (for the MCR729, typically
100 ohms), so the drained charge can be expressed by
Equation (6) [or (7)] indicates two things:
1. The rate of change of input trigger charge decreases as
temperature (life time) increases.
2. The larger the pulse width of gate trigger current, the
faster the rate of change of Qin with respect to change
in temperature. Figure 3.11 shows these trends.
V
Qdr GC t
Rs
(3)
Combining equations (1), (2), and (3), we get
V
Qin IGt (Qtr GC t) exp. t
t1
Rs
(4)
*VGC is not independent of IG. For example, for the
MCR729 the saturation VGC is typically 1 V, but at lower
IG’s the VGC is also smaller, e.g. for IG = 5 mA, VGC is
typically 0.3 V.
Note that at region A and C of Figure 3.3(c) Qin has an
increasing trend with pulse width as qualitatively described
by Equation (4).
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APPENDIX III
TTL SOA TEST CIRCUIT
Using the illustrated test circuit, the two TTL packages
(quad, 2−input NAND gates) to be tested were powered by
the simple, series regulator that is periodically shorted by
the clamp transistor, Q2, at 10% duty cycle rate. By
varying the input to the regulator V1 and the clamp pulse
width, various power levels can be supplied to the TTL
load. Thus, as an example, VCC could be at 5 V for 90 ms
and 10 V for 10 ms, simulating a transient on the bus or a
possibly shorted power supply pass transistor for that
duration. These energy levels are progressively increased
until the gate (or gates) fail, as detected by the status of the
output LEDs, the voltage and current waveforms and the
device case temperature.
VCC
V1
MJE220
Q1
220 5.6 V
2W 1W
V1
1k
Q2
G4
0.1 μF
3.9 M
MC14011
470
300
(2) MC7400
DUT
T1
G2
T2
100 k
5 ms < T2 < 250 ms
50 ms < T2 < 1.9 s
0.47 μF
500 k
1N914
2.2 M
5M
1N914
10% DUTY CYCLE GENERATOR
Figure 9.2. TTL SOA Test Circuit
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236
220
2D
V2
G1
10 k
VCC
VCC
10 k
SQUARE WAVE GENERATOR
f 1 Hz
V2
10 k
Q4
LED
1k
10 k
10 k
2A
1D
MJE230
2N3904 Q3
1A
2N3904
G3
10 V
1N5240
10 M
1N4739
220
V2 = 10 V
100 μF
LED
300
1k
VCC
APPENDIX IV
SCR CROWBAR LIFE TESTING
by the collector resistors of the respective gate drivers and
the supply voltage, VCC2; thus, for IGT ≈ 100 mA, VCC2 ≈
30 V, etc.
The LEDs across the storage capacitors show the state of
the voltage on the capacitors and help determine whether
the circuit is functioning properly. The timing sequence
would be an off LED for the one−second capacitor dump
period followed by an increasingly brighter LED during
the capacitor charge time. Monitoring the current of VCC1
will also indicate proper operation.
The fixture’s maximum energy limits are set by the
working voltage of the capacitors and breakdown voltage
of the transistors. For this illustration, the 60 V, 8400 μF
capacitors (ESR ≈ 20 mΩ) produced a peak current of
about 2500 A lasting for about 0.5 ms when VCC1 equals
60 V. Other energy values (lower ipk, greater tw) can be
obtained by placing a current limiting resistor between the
positive side of the capacitor and the crowbar SCR anode.
This crowbar life test fixture can simultaneously test ten
SCRs under various crowbar energy and gate drive
conditions and works as follows.
The CMOS Astable M.V. (Gates 1 and 2) generate an
asymmetric Gate 2 output of about ten seconds high, one
second low. This pulse is amplified by Darlington Q22 to
turn on the capacitor charging transistors Q1−Q10 for the
ten seconds. The capacitors for crowbarring are thus
charged in about four seconds to whatever power supply
voltage to which VCC1 is set. The charging transistors are
then turned off for one second and the SCRs are fired by an
approximately 100 μs delayed trigger derived from Gates 3
and 4. The R−C network on Gate 3 input integrates the
complementary pulse from Gate 1, resulting in the delay,
thus insuring non−coincident firing of the test circuit. The
shaped pulse out of Gate 4 is differentiated and the
positive−going pulse is amplified by Q21 and the following
ten SCR gate drivers (Q11−Q20) to form the approximate 2
ms wide, 1 μs rise time, SCR gate triggers, IGT. IGT is set
VDD
+ 15 V
0.1 μF
100 k
10 k
Q21
4
3
MJE803
1N914
VSS
0.001 μF
MC14011B
VCC1
470
+15 V
1
22 M
22 M
VCC2
2.2 k
2W
+15 V
2
MJE250
Q1
10 k
MJE250
Q22
470
2.2 k
VCC1
2W
470
2.2 M
MJE803
R1
2.7 k
2.2 k
2W
0.47 μF
Q10
MJE250
2.7 k
1W
(10) LED
270
VCC2
470
8400 μF
C10
MJE250
Q20
Figure 9.3. Schematic for SCR Crowbar Life Test
237
2.2 k
DUT #1
100
5W
270
DUT #10
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Q11
8400 μF
C1
1W
1N914
100
5W
2.2 k
APPENDIX V
APPENDIX VI
DERIVATION OF THE RMS CURRENT
OF AN EXPONENTIALLY DECAYING
CURRENT WAVEFORM
DERIVATION OF I2t FOR VARIOUS TIMES
Δt = Z(θ)PD
Thermal Equation
i = Ipke−t/τ
Ipk
where
Z(θ) = r(t)RθJC
r(t) = K t
and
Therefore, for the same Δt,
T=5τ
Irms Dt K t1 RqJCPD K t2 RqJC PD ,
2
1
T
1
i2(t)dt
T 0
PD
PD
1
2
T
1
(I e–t
t)2dt
T 0 pk
Ipk2 e–2t
t T
T (–2
t)
0
–
–2t (e–2T
t – e0)
Ipk2
(e–10 – 1)
10
2
2
tt21
Multiplying both sides by (t1/t2),
2
t 1
2
I1 t1
t 1
2 t1
2
1
,
t1
t2
t2
I22t2
1
2
I12t1 I22t2
where T = 5τ,
2
tt21 II12RR ,
2
I1
I22
1
2
Ipk2
T
1
1
2
Ipk
Irms 0.316 Ipk
10
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tt1
2
APPENDIX VII
THERMAL RESISTANCE CONCEPTS
The basic equation for heat transfer under steady−state
conditions is generally written as:
q = hAΔT
The thermal resistance junction to ambient is the sum of
the individual components. Each component must be
minimized if the lowest junction temperature is to result.
The value for the interface thermal resistance, RθCS, is
affected by the mounting procedure and may be significant
compared to the other thermal−resistance terms.
The thermal resistance of the heat sink is not constant; it
decreases as ambient temperature increases and is affected
by orientation of the sink. The thermal resistance of the
semiconductor is also variable; it is a function of biasing
and temperature. In some applications such as in RF power
amplifiers and short−pulse applications, the concept may
be invalid because of localized heating in the semiconductor chip.
(1)
where q = rate of heat transfer or power dissipation (PD),
h = heat transfer coefficient,
A = area involved in heat transfer,
ΔT = temperature difference between regions of
heat transfer.
However, electrical engineers generally find it easier to
work in terms of thermal resistance, defined as the ratio of
temperature to power. From Equation (1), thermal resistance, Rθ, is
Rθ = ΔT/q = 1/hA
(2)
The coefficient (h) depends upon the heat transfer mechanism used and various factors involved in that particular
mechanism.
An analogy between Equation (2) and Ohm’s Law is
often made to form models of heat flow. Note that ΔT could
be thought of as a voltage; thermal resistance corresponds
to electrical resistance (R); and, power (q) is analogous to
current (l). This gives rise to a basic thermal resistance
model for a semiconductor (indicated by Figure 9.4).
The equivalent electrical circuit may be analyzed by
using Kirchoff’s Law and the following equation results:
TJ = PD(RθJC + RθCS + RθSA) + TA
where
TJ, JUNCTION TEMPERATURE
RθJC
TC, CASE TEMPERATURE
TS, HEAT SINK
TEMPERATURE
(3)
TA, AMBIENT
TEMPERATURE
TJ = junction temperature,
PD = power dissipation,
RθJC = semiconductor thermal resistance
(junction to case),
RθCS = interface thermal resistance
(case to heat sink),
RθSA = heat sink thermal resistance
(heat sink to ambient),
TA = ambient temperature.
PD
RθCS
RθSA
REFERENCE TEMPERATURE
Figure 9.4. Basic Thermal Resistance
Model Showing Thermal to Electrical
Analogy for a Semiconductor
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APPENDIX VIII
DERIVATION OF RFI DESIGN EQUATIONS
The relationship of flux to voltage and time is E = N
where:
df
dt
N is total turns
Erms is line voltage
tr is allowable current rise time in seconds
BMAX is maximum usable flux density of core material
Ac is usable core area in square inches
Window area necessary is:
or E = NAc dB since φ = BAc and Ac is a constant.
dt
Rearranging this equation and integrating we get:
E dt = NAc (B2 − B1) = NAc Δ B
(1)
Aw = N Awire3
which says that the volt−second integral required determines the size of the core. In an L−R circuit such as we
have with a thyristor control circuit, the volt−second
characteristic is the area under an exponential decay. A
conservative estimate of the area under the curve may be
obtained by considering a triangle whose height is the peak
line voltage and the base is the allowable switching time.
(4)
The factor of 3 is an approximation which allows for
insulation and winding space not occupied by wire.
Substituting equation (3) in (4):
Aw 10.93 Erms tr 106
Awire 3
BMAX Ac
(The factor 10.93 may be rounded to 11 since two
significant digits are all that are necessary.)
Eptr
The area is then 1/2 bh or
.
2
Substituting in Equation (1):
Eptr
N Ac D B
2
The factor AcAw can easily be found for most cores and is
an easy method for selecting a core.
(2)
Ac Aw 33 Erms trAwire 106
BMAX
where:
Ep is the peak line voltage
tr is the allowable current rise time
N is the number of turns on the coil
Ac is the usable core area in cm2
Δ B is the maximum usable flux density of the core
material in W/m2
In this equation, the core area is in in2. To work with
circular mils, multiply by 0.78 10−6 so that:
Rewriting Equation (2) to change ΔB from W/m2 to gauss,
substituting 2 Erms for Ep and solving for N, we get:
where Awire is the wire area in circular mils.
Inductance of an iron core inductor is
N
Ac Aw 2 Erms tr
0.707 Erms tr 108
108 BMAX Ac
2 Ac D B
L
Ac in this equation is in cm2. To change to in2, multiply Ac
by 6.452. Then:
N
10.93 Erms tr 106
BMAX Ac
26 Erms trAwire
BMAX
3.19 N2 Ac 10–8
1
Ig mc
Rearranging terms,
(3)
Ig 3.19 N2 Ac 10–8 1c
– m
L
APPENDIX IX
BIBLIOGRAPHY ON RFI
Electronic Transformers and Circuits, Reuben Lee, John Wiley and Sons, Inc., New York, 1955.
Electrical Interference, Rocco F. Ficchi, Hayden Book Company, Inc., New York, 1964.
“Electromagnetic−Interference Control,” Norbert J. Sladek, Electro Technology, November, 1966, p. 85.
“Transmitter−Receiver Pairs in EMI Analysis,” J. H. Vogelman, Electro Technology, November, 1964, p. 54.
“Radio Frequency Interference,” Onan Division of Studebaker Corporation, Minneapolis, Minnesota.
“Interference Control Techniques,” Sprague Electric Company, North Adams, Massachusetts, Technical Paper 62−1, 1962.
“Applying Ferrite Cores to the Design of Power Magnetics,” Ferroxcube Corporation of America, Saugerties, New York, 1966.
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