SANKEN STR

INTERIM DATA SHEET
(Subject to change without notice)
February 22, 2000
Data Sheet
28102.8
Series STR-F6600
OFF-LINE QUASI-RESONANT
FLYBACK SWITCHING REGULATORS
The Series STR-F6600 is specifically designed to satisfy the requirements for increased integration and reliability in off-line quasi-resonant
flyback converters. The series incorporates a primary control and drive
circuit with discrete avalanche-rated power MOSFETs.
OSC.
FDBK
LATCH
3
4
DRAIN
SUPPLY
5
2
SOURCE
GROUND
1
OVER-CURRENT
& FEEDBACK
VIN
OCP
UVLO
OVP
TSD
Dwg. PK-011-1
ABSOLUTE MAXIMUM RATINGS
at TA = +25°C
Control Supply Voltage, VIN . . . . . . . . 35 V
Drain-Source Voltage, VDS
Series STR-F6620 . . . . . . . . . . . . 450 V
Series STR-F6630 . . . . . . . . . . . . 500 V
Series STR-F6650 . . . . . . . . . . . . 650 V
Series STR-F6670 . . . . . . . . . . . . 900 V
Drain Switching Current, ID . . . See Table
Peak Drain Current, IDM . . . . . . See Table
Avalanche Energy, EAS . . . . . . . See Table
OCP/FB Voltage Range,
VOCP . . . . . . . . . . . . . . . -0.3 V to +6 V
Package Power Dissipation, PD
control (VIN x IIN(ON)) . . . . . . . . . 0.8 W
total . . . . . . . . . . . . . . . . . . . See Graph
FET Channel Temperature, TJ . . . +150°C
Internal Frame Temperature, TF . . +125°C
Operating Temperature Range,
TA . . . . . . . . . . . . . . . -20°C to +125°C
Storage Temperature Range,
TS . . . . . . . . . . . . . . . . -40°C to +125°C
Covering the power range from below 25 watts up to 300 watts for
100/115/230 VAC inputs, and up to 150 watts for 85 to 265 VAC
universal input, these devices can be used in a range of applications,
from battery chargers and set top boxes, to televisions, monitors, and
industrial power supply units.
Cycle-by-cycle current limiting, under-voltage lockout with hysteresis, over-voltage protection, and thermal shutdown protects the power
supply during the normal overload and fault conditions. Over-voltage
protection and thermal shutdown are latched after a short delay. The
latch may be reset by cycling the input supply. Low-current startup and
a low-power standby mode selected from the secondary circuit completes
a comprehensive suite of features. The series is provided in a five-pin
overmolded TO-3P style package, affording dielectric isolation without
compromising thermal characteristics.
FEATURES
■ Flyback Operation with Quasi-Resonant Soft Switching
for Low Power Dissipation and EMI
■ Rugged Avalanche-Rated MOSFET
■ Choice of MOSFET Voltage and rDS(on)
■ Full Over-Current Protection (no blanking)
■ Under-Voltage Lockout with Hysteresis
■ Over-Voltage Protection
■ Direct Voltage Feedback
■ Low Start-up Current (<400 µA)
■ Low-Frequency, Low-Power Standby Operation
■ Overmolded 5-Pin Package
Always order by complete part number, e.g., STR-F6652 .
™
TM
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
FUNCTIONAL BLOCK DIAGRAM
V IN
4
DRIVE
REG.
R
UVLO
OVER-VOLT.
PROTECT
FAULT
LATCH
S
3
DRAIN
2
SOURCE
1
FEEDBACK &
OVER-CURRENT
PROTECTION
Q
REF.
TSD
OSC
–
r SS
+
1.45 V
c SS
–
+
0.73 V
GROUND
Dwg. FK-002-6
NORMALIZED ALLOWABLE AVALANCHE ENERGY in mJ
1.0
0.8
0.6
Allowable package power dissipation curves
are shown on page 10.
0.4
0.2
0
25
50
75
100
125
STARTING CHANNEL TEMPERATURE in °C
Dwg.
2
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
Copyright © 2000 Allegro MicroSystems, Inc.
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
OUTPUT MAXIMUM RATINGS at TA = +25°C
VDSS (V)
rDS(on) (Ω)
EAS (mJ)*
ID (A)†
IDM (A)
POUT (W)
STR-F6624
450
0.92
204
16
19
STR-F6626
450
0.58
327
16
26
STR-F6628
450
0.35
647
22
36
STR-F6632
500
2.54
7.4
9.0
11.2
STR-F6652
650
2.8
126
7.9
10
STR-F6653
650
1.95
260
5.6
14
STR-F6654
650
1.15
399
9.7
18
STR-F6656
650
0.71
521
16
25
STR-F6672
900
7.7
163
4.6
6.4
STR-F6674
900
4.49
242
6.0
9.2
STR-F6676
900
2.81
275
7.8
12
98
130
145
190
225
290
36
50
40
86
58
120
92
190
150
300
25 (no heatsink)
50 (with heat sink)
28
76
44
115
Part Number
at VIN (V rms)
100
120
100
120
100
120
100
120
85-265
220
85-265
220
85-265
220
85-265
220
220
220
85-265
220
85-265
220
* Derate per graph, page 2
† Derate per graph, page 12
3
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
ELECTRICAL CHARACTERISTICS at TA = +25°C, VIN = 18 V (unless otherwise specified).
Limits
Characteristic
Symbol
Test Conditions
Min.
Typ.
Max.
Units
On-State Voltage
VINT
Turn-on, increasing VIN
14.4
16
17.6
V
Under-Voltage Lockout
VINQ
Turn-off, decreasing VIN
9.0
10
11
V
Over-Voltage Threshold
VOVP(th)
Turn-off, increasing VIN
20.5
22.5
24.5
V
Drain-Source Breakdown Voltage
VBR(DSS)
ID = 300 µA
–
–
V
IDSS
At VDS max
–
–
300
µA
VS = 10 V, ID = 0.9 A, TJ = +25°C
–
–
see table
Ω
toff
Drain waveform high
45
–
55
µs
tw(th)
Drain waveform high1
–
–
1.0
µs
toff
Drain waveform high1
–
–
1.5
µs
Drain waveform low to high1
0.68
0.73
0.78
V
Oscillation synchronized2
1.3
1.45
1.6
V
1.2
1.35
1.5
mA
Drain Leakage Current
On-State Resistance
Maximum Off Time
Minimum Pulse Duration for Input of
Quasi-Resonant Signals
Minimum Off Time
Feedback Threshold Voltage
rDS(ON)
VFDBK
VDS max
Over-Current Protection/Feedback
Sink Current
IOCP/FB
VOCP/FB = 1.0 V
Latch Holding Current
IIN(OVP)
VIN reduced from 24.5 V to 8.5 V
–
–
400
µA
Latch Release Voltage
VIN
IIN ≤ 20 µA, VIN reduced from 24.5 V
6.6
–
8.4
V
VDD = 200 V, ID = 0.9 A
–
–
250
ns
Switching Time
tf
Supply Current
IIN(ON)
Operating3
–
–
30
mA
IIN(OFF)
Increasing VIN prior to oscillation
–
–
100
µA
VWM(RMS)
All terminals simultaneous reference to a metal plate against
the backside
2000
–
–
V
Thermal Resistance
RθJM
Output channel to mounting frame
–
–
1.75
°C/W
Thermal Shutdown
TJ
140
–
–
°C
Insulation RMS Voltage
Notes: Typical Data is for design information only.
1. Feedback is square wave, VIM = 2.2 V, th = 1 µs, tl = 35 µs.
2. For quasi-resonant operation, the input signal must be longer than tw(th) and greater than VFDBK.
3. Feedback is square wave, VIM = 2.2 V, th = 4 µs, tl = 1 µs.
4
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Functional Description and Operation
The voltage on the VIN terminal (pin 4) controls startup
and shutdown of the Series STR-F6600 devices.
Figure 1 shows a typical start up circuit. The VIN
terminal voltage during startup is shown in figure 2.
At startup, C2 is charged through the startup resistor RS.
When the VIN terminal voltage reaches 16 V (typ.), the
control circuit enables regulator operation. Once the
regulator starts, it draws up to 30 mA from C2 causing the
voltage on C2 to fall momentarily. Once the regulator
output voltage is established, the drive winding D starts to
charge C2 via D2. The voltage on C2 thus recovers to the
nominal drive voltage (18 V).
As shown in figure 3, the input current is below 100 µA
(at TM = 25°C) prior to control circuit turn on. The latch
circuit holding current is 400 µA (max.). To ensure latch
operation, the current in RS at the lowest ac input voltage
should be at least 500 µA.
IIN
IIN(ON)
VINQ
30 mA
(MAX.)
Figure 1 – Start-Up Circuit
100 µA
(MAX.)
16 V ON-STATE VOLTAGE (VINT)
(TYP.)
VINT
VIN
IIN(OFF)
11 V
(MAX.)
14.4 V
(MIN.)
VIN
Figure 3 – Supply Terminal Current, IIN
UNDER-VOLTAGE LOCKOUT (VINQ)
STARTUP
DELAY
OPERATION START
11 V
(MAX.)
DRIVE WINDING
VOLTAGE
TIME
Figure 2 – Waveform of VIN Terminal Voltage
at Startup
The value of RS thus determines the charge time of C2
and thus the startup delay. RS is typicaly 68 kΩ for wide
operation (90 V ac to 265 V ac) and 100 kΩ for 220 volt
ac operation.
The choice of C2 is a compromise between an acceptable startup delay (in conjunction with RS) and a hold-up
time sufficient to keep pin 4 above its under-voltage
shutdown threshold of 11 V. Typically C2 is in the range
of 47 µF to 100 µF.
continued, next page...
5
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Functional Description and Operation (cont’d)
The drive winding voltage is set such that in normal
operation the C2 voltage is above the specified maximum
shutdown voltage (11 V) and below the specified minimum over-voltage threshold (20.5 V).
comparator output pre-terminates the oscillator, which
turns off the MOSFET drive signal.
In applications where there is a significant variation in
load current, the VIN terminal voltage may vary, as shown
in figure 4. This is due to peak charging of C2. In this
case, adding a resistor in the range of a few ohms to tens of
ohms in series with the rectifier diode D2 will bring the
voltage variation within limits.
Fixed 50 µs Off-Time: Soft-Start Mode
The MOSFET is turned on again when either cSS
discharges or a quasi-resonance signal is detected on pin 1.
This is the mode of operation in the absence of a quasiresonance signal on pin 1 (see figure 5), and occurs at
VIN
Figure 5 – Soft-Start Operation
IOUT
Figure 4 – Output Current IOUT – Terminal Voltage VIN
Soft Start, Quasi Resonant and Voltage Regulation
Refer to the Functional Block Diagram and the Typical
Application Diagram (figure 6). The internal oscillator
uses the charge/discharge of an internal 4700 pF capacitor
(cSS) to generate the MOSFET drive signals.
The regulator has two modes of operation:
1. fixed 50 µs off time (soft start) and
2. demagnetization sensing quasi-resonant mode —
normal operation.
In both cases, voltage regulation is achieved by taking
the composite optocoupled voltage error and superimposed
drain current ramp (current-mode control) and comparing
this to an internal 0.73 V reference. The FBK/OCP
6
startup and in overload. It also can be commanded externally to provide low-power standby operation.
In the absence of a feedback signal (such as at startup,
or a short circuit) the drain current ramp, sensed across R5
and noise filtered by R4/C5 appears on pin 1. When the
ramp voltage on C5 exceeds the 0.73 V reference signal,
the FBK/OCP comparator changes state, shutting down the
oscillator and turning off the MOSFET. Thus the voltage
on cSS is held high (6.5 V) by the comparator. When the
comparator changes state, cSS discharges via rSS; the
voltage on cSS ramps down until it reaches 3.7 V. The
oscillator turns on the MOSFET. This ramp-down time is
internally trimmed to 50 µs. The comparator changes state
again and the cycle repeats. Thus in the absence of
feedback, the current-sense resistor R5 accurately controls
the MOSFET maximum current.
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Functional Description and Operation (cont’d)
+ OUTPUT
4
DRIVE
REG.
OVER-VOLT.
PROTECT
FAULT
LATCH
FULL-BRIDGE
RECTIFIER
AC INPUT
S
+
3
R
UVLO
2
VOLTAGE
SENSE
Q
REF.
+
TSD
OSC
+
– OUTPUT
–
+
1.45 V
1
–
+
0.73 V
★
Dwg. EK-003-5A
Figure 6 – Series STR-F6600 Typical Application
WARNING — These devices are designed to be operated at lethal voltages and energy levels. Circuit
designs that embody these components must conform with applicable safety requirements. Precautions must be taken to prevent accidental contact with power-line potentials. Do not connect
grounded test equipment.
The use of an isolation transformer is recommended during circuit development and breadboarding.
Soft Start with Voltage Feedback (refer to figure 7)
Output voltage control is achieved by sensing the optocoupled feedback current (proportional to the output
voltage error signal) across resistor R4 and summing this
with the drain current ramp on R5. The signal on pin 1 is
therefore the opposite of the output voltage error signal
and the drain current ramp. The dc bias signal across R4 is
thus a function of the load. Consequently at light load, the
bias signal on R4 is closer to the threshold voltage of the
comparator.
To eliminate the possibility of false shutdown at
MOSFET turn on (when there is a current spike due to the
discharge of primary capacitance), a constant-current sink
of 1.35 mA is turned on, effectively lowering the input
impedance on pin 1, and momentarily increasing the
shutdown threshold.
7
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Functional Description and Operation (cont’d)
t = π√LpC4
f R = 1/2π√LpC4
VP
VDS
VP
VIN
VDS (min)
VD
Figure 7 - Voltage Regulation Waveforms
VOCP ≈ 2.8 V
Vth(2) ≈ 1.45 V
Vth(1) ≈ 0.73 V
Normal Operation (Quasi-Resonant) Mode
Refer to the Functional Block Diagram, Typical Application diagram (figure 6), and Quasi-Resonance Waveforms (figure 8).
Regulation is achieved as in fixed off-time mode but
instead of having a fixed off-time, the demagnetization of
the transformer is sensed by a second comparator. This
comparator threshold, Vth(2) is nominally 1.45 V. Quasiresonance sensing makes use of the natural magnetizing
and leakage inductances and self-capacitances of the
power circuit.
Figure 8 shows the drain voltage waveform, (VDS), on
pin 3 of the STR-F66xx, as well as VP, the voltage on the
primary of the transformer.
Once the current in the output diode stops flowing, the
primary stored energy ‘rings’ as shown by VP and VDS.
The resonant frequency (fr) is determined by the magnetizing inductance of the transformer and the capacitor C4.
8
VFDBK
ID
Dwg. GK-021
Figure 8 – Quasi-Resonance Waveforms
The addition of this capacitor sets the ringing frequency
and reduces the harmonic content in the VDS waveform,
lowering EMI. Also since VDS falls to a minimum during
the first half-cycle of the ring this point can be sensed and
used to turn on the MOSFET with minimum voltage
across it. Thus the MOSFET is low voltage and zero
current switched (LVS/ZCS).
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Functional Description and Operation (cont’d)
The voltage VOCP (pin 1) has the same form as the VDS
waveform. The condition for quasi-resonant operation is
given by:
2.0 V < VOCP > 5.5 V for >1 µs
Transformer design is exactly as for any other discontinuous-mode type flyback.
Latch Circuit
The latch circuit keeps the oscillator output low to
inhibit operation of the regulator when over-voltage
protection (OVP) and thermal shutdown (TSD) circuits are
in operation. As long as the latch hold-in current is
400 µA (max., supplied via RS) with VIN at 8.5 V (pin 4),
the regulator will stay in the off state.
For optimum EMI/efficiency performance, quasiresonance turn off is achieved when the MOSFET is at
zero voltage and zero current; that is, at one half cycle of
the quasi-resonance frequency, fr.
An internal noise filter provides 10 µs of noise immunity to prevent spurious operation of the over-voltage
protection or thermal shutdown.
Over-Current Protection (OCP) Functions
With the latch ‘on’, the voltage on pin 4 cycles between
16 V and 10 V as shown in figure 9. This is due to the
higher current drawn when the pin 4 is at 16 V compared
to that drawn close to shutdown (10 V).
Refer to the Functional Block diagram and Typical
Application diagram (figure 6).
The regulator implements pulse-by-pulse over-current
protection, which limits the maximum drain current in the
MOSFET on every pulse by switching off the internal
drive to the MOSFET, and the MOSFET drain current is
detected across R5.
Drive Circuit
Refer to the Functional Block Diagram.
This circuit is driven from the oscillator and provides
the current drive to charge and discharge the MOSFET
gate-source capacitance, thereby switching the device on
and off. The basic circuit configuration is totem-pole type
with an additional limiting resistor in the gate circuit at
turn on. This limits the turn on speed of the MOSFET,
thereby reducing EMI due to the discharge of primary
capacitance. This is possible because of the low-voltage
switching, zero-current switching nature of the turn on.
The value of the turn-off resistance is lower, allowing
the device turn-off current to be increased. This reduces
the turn-off loss in the MOSFET.
The gate drive voltage (8.3 V) is such that even with
0.73 V across R5 (drain current sense resistor), the
MOSFET is fully enhanced, allowing full use to be made
of its high current handling capacity.
Pulling VIN (pin 4) below 6.5 V will reset the latch
circuit, re-enabling the regulator.
Thermal Shutdown
This internal feature triggers the latch if the internal
frame temperature exceeds 140°C (typ.).
The temperature is sensed on the control IC, but also
protects against overheating of the MOSFET as the
MOSFET and the control IC are mounted on the same lead
frame. Additionally, protection is provided for other onboard components.
VIN
16 V
(TYP.)
10 V
(TYP.)
TIME
Figure 9 – Example of VIN Terminal Voltage
Waveform at Latch Circuit On
9
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Functional Description and Operation (cont’d)
Over-Voltage Protection Circuit
VOUT
This feature of the STR-F66xx triggers the latch circuit
when the VIN voltage (pin 4) exceeds 22.5 V (typ.).
Because the voltage on pin 4 is proportional to the output
voltage (they are linked by the transformer turns ratio), the
regulator protects the output against over-voltage. This
function is entirely independant of the output-voltage
regulation loop and indeed will protect against output
over-voltage should the voltage error signal be lost. The
measure of over-voltage is given by:
AC LOW
AC HIGH
VOUT(OVP) = VOUT(NOM) x VIN(OVP)/VIN(NOM)
IOUT
where VIN(OVP) is the drive voltage on pin 4.
Figure 10 – Power Supply Output
Overload Characteristics
In an over-voltage sensitive application, the drive
voltage can be set to close to 20 V and thus will protect the
output, if it rises more than 10% above nominal.
ALLOWABLE PACKAGE POWER DISSIPATION
STR-F665x
MOUNTING SURFACE
TEMPERATURE
STR-F6656, 56 W MAX.
STR-F6654, 55 W MAX.
STR-F6653, 48 W MAX.
STR-F6652, 43 W MAX.
60
40
RECOMMENDED MAX.
FRAME TEMP. = +115°C
LIMITED BY FRAME
TEMP. = +125°C MAX.
20
CONTROLLER
0.8 W MAX.
FREE AIR
ALL DEVICES
2.8 W MAX.
0
20
60
100
TEMPERATURE in °C
140
Dwg. GK-0
ALLOWABLE PACKAGE POWER DISSIPATION in WATTS
ALLOWABLE PACKAGE POWER DISSIPATION in WATTS
60
STR-F667x
MOUNTING SURFACE
TEMPERATURE
STR-F6676, 53 W MAX.
STR-F6672, 45 W MAX.
40
RECOMMENDED MAX.
FRAME TEMP. = +115°C
LIMITED BY FRAME
TEMP. = +125°C MAX.
20
CONTROLLER
0.8 W MAX.
FREE AIR
ALL DEVICES
2.8 W MAX.
0
20
60
100
TEMPERATURE in °C
140
Dwg. GK-0
10
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
MOSFET Safe Operating Areas
(single pulse at TA = +25°C)
STR-F6652
STR-F6653
50
50
15
15
LIMITED
BY rDS(on)
1.5
0.5
TA = +25°C
0.15
LIMITED
BY rDS(on)
5
tw
=1
ms
SI
NG
LE
1.5
=
0.1
ms
SI
NG
LE
PU
LS
E
PU
LS
E
LIMITED BY VDS max
5
DRAIN CURRENT in AMPERES
=0
tw
.1
=1
ms
ms
SI
NG
SIN
LE
GL
EP
PU
LS
UL
E
SE
LIMITED BY VDS max
DRAIN CURRENT in AMPERES
tw
tw
0.5
TA = +25°C
0.15
0.05
0.05
3.0
10
30
100
10
3.0
300
30
100
300
DRAIN-SOURCE VOLTAGE in VOLTS
DRAIN-SOURCE VOLTAGE in VOLTS
Dwg. GK
Dwg. GK
STR-F6654
STR-F6656
50
50
tw
5
=1
ms
SI
NG
LE
PU
LS
E
LIMITED
BY rDS(on)
PU
LS
E
1.5
0.5
TA = +25°C
0.15
0.05
tw
5
=1
=0
.1
ms
SI
NG
LE
ms
SI
NG
LE
PU
LS
E
PU
LS
E
1.5
LIMITED BY VDS max
tw
15
LIMITED BY VDS max
DRAIN CURRENT in AMPERES
LIMITED
BY rDS(on)
=0
.1
ms
SI
NG
LE
DRAIN CURRENT in AMPERES
tw
15
0.5
TA = +25°C
0.15
0.05
3.0
10
30
100
3.0
300
DRAIN-SOURCE VOLTAGE in VOLTS
10
30
100
300
DRAIN-SOURCE VOLTAGE in VOLTS
Dwg. GK
Dwg. GK
11
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
MOSFET Safe Operating Areas (cont)
(single pulse at TA = +25°C)
STR-F6672
STR-F6676
50
50
15
15
tw
5
=0
.1
ms
SIN
tw
GL
=1
EP
ms
UL
SI
SE
NG
LE
PU
LS
E
LIMITED
BY rDS(on)
1.5
0.5
DRAIN CURRENT in AMPERES
5
tw
LIMITED
BY rDS(on)
=1
=0
.1
ms
SI
NG
LE
ms
SI
NG
LE
1.5
PU
LS
E
PU
LS
E
0.5
TA = +25°C
LIMITED BY
TA = +25°C
0.15
LIMITED BY V
DRAIN CURRENT in AMPERES
tw
0.15
0.05
0.05
3.0
10
30
100
3.0
300
10
30
100
300
DRAIN-SOURCE VOLTAGE in VOLTS
DRAIN-SOURCE VOLTAGE in VOLTS
Dwg. GK
Dwg. GK
Drain Switching Current (ID) Derating
S.O.A. Derating
1.0
20
MAXIMUM SWITCHING CURRENT (ID) in AMPERES
TA = -20°C to +125°C
NORMALIZED SAFE OPERATING AREA
0.8
0.6
0.4
0.2
0
25
50
75
100
16
STR-F6656
12
STR-F6654
8.0
STR-F6652 & STR-F6672
STR-F6653
4.0
STR-F6672
0
125
0.8
FRAME TEMPERATURE in °C
0.9
Dwg. G
12
1.0
1.1
SOURCE-TO-GROUND VOLTAGE (V2-V5) in VOLTS
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
Dwg
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Transient Thermal Impedance
10
1.0
1.0
THERMAL IMPEDANCE (ZθJC) in °C/W
THERMAL IMPEDANCE (ZθJC) in °C/W
STR-F665x
10
STR-F6652
STR-F6653
0.1
STR-F6654
STR-F6656
0.01
STR-F667x
0.1
STR-F6672
STR-F6676
0.01
0.001
0.001
0.0001
10 n
100 n
1µ
10 µ
100 µ
0.0001
1m
POWER PULSE DURATION in SECONDS
10 m
100 m
10 n
100 n
1µ
10 µ
100 µ
1m
10 m
100 m
POWER PULSE DURATION in SECONDS
13
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Applications Information
Capacitors
Error Amplifier
Electrolytic capacitors carrying large switching frequency ripple currents (C1 and the output capacitors)
should be capable of handling the high rms currents
involved. Capacitors with low ESR are suitable. The
quasi-resonance capacitor C4 should be a high-voltage
ceramic type suitable for pulsed current operation.
A standard TL431 transconductance amplifier or an
Allegro/Sanken Series SE error-amplifier IC can be used.
The Series SE is particularly well-suited to high-voltage
(70 V to 140 V) power outputs.
The safety critical nature of the off-line application
must be considered when selecting both X and Y capacitors for common- and differential-mode noise filtering.
Use of the low-noise quasi-resonant Series STR-F6600
will allow optimization of these capacitor values.
If a Series SE error-amplifier IC is used, normally phase
compensation is not required. Should additional highfrequency attenuation be required, a capacitor (0.022 µF or
less) can be connected across the primary side (collectoremitter) of the optocoupler, a diode to maintain quasiresonant operation should be added in series with the
phototransistor emitter.
C5, the 470 pF filtering capacitor should be a 50 V
temperature-stable (COG) ceramic type.
Resistors
Resistor R5 carries high-frequency current, and so a low
internal inductance type of 1 W rating should be used.
Resistor R9 (RS) should be 2 W metal oxide.
All other resistors can be 1/4 watt or 1/2 watt metal
film.
Diodes
Diodes carrying the high-frequency flyback currents
(such as the transformer rectifier diodes) should have a fast
or ultrafast reverse-recovery characteristic, adequate
current handing and peak reverse-voltage rating. Allegro/
Sanken supplies a range of suitable diodes, and these are
described in the Allegro/Sanken short-form catalogue
(AMS-127) or latest issue of Bulletin D01EC0.
Optocoupler
Both Toshiba TLP 621 and Siemens SFH 610A2 or
615A2 are suitable. A current-transfer ratio of 50% to
200% is acceptable.
The products described here are manufactured in Japan by Sanken
Electric Co., Ltd. for sale by Allegro MicroSystems, Inc.
Sanken Electric Co., Ltd. and Allegro MicroSystems, Inc. reserve the
right to make, from time to time, such departures from the detail
specifications as may be required to permit improvements in the
performance, reliability, or manufacturability of their products.
Therefore, the user is cautioned to verify that the information in this
publication is current before placing any order.
These products are not authorized for use as critical components in
life-support appliances, devices, or systems without express written
approval.
The information included herein is believed to be accurate and
reliable. However, Sanken Electric Co., Ltd. and Allegro
MicroSystems, Inc. assume no responsibility for its use; nor for any
infringements of patents or other rights of third parties which may
result from its use.
14
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
TM
™
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Dimensions in Inches
(for reference only)
0.614
±0.008
T M REF.
0.126 ø
0.216
±0.008
±0.008
0.136
±0.004
0.906 ±0.012
0.216 ±0.008
0.132
±0.004
0.276
±0.016
0.216
0.033
+0.008
–0.004
0.026
1
5
+0.008
–0.004
0.177
±0.028
0.100
±0.004
AT ROOT
Dwg. MK-003-50 in
Recommended mounting hardware torque: 4.34 – 5.79 lbf•ft.
Recommended silicone grease: Dow Corning SC102, Toshiba YG6260, Shin-Etsu G746., or equivalent
15
Series STR-F6600
OFF-LINE
QUASI-RESONANT FLYBACK
SWITCHING REGULATORS
Dimensions in Millimeters
(controlling dimensions)
15.6
±0.2
T
M
REF.
3.2 ø
5.5
±0.2
±0.2
3.45
±0.1
23.0 ±0.3
5.5 ±0.2
3.35
±0.1
7.0
±0.5
5.5
0.85
+0.2
–0.1
0.65
1
5
+0.2
–0.1
4.5
±0.7
2.54
±0.1
AT ROOT
Dwg. MK-003-50 mm
Recommended mounting hardware torque: 6 – 8 kg•cm or 0.588 – 0.784 Nm.
Recommended silicone grease: Dow Corning SC102, Toshiba YG6260, Shin-Etsu G746., or equivalent
16
115 Northeast Cutoff, Box 15036
Worcester, Massachusetts 01615-0036 (508) 853-5000
TM
™