BOURNS TISP3380F3SL-S

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oH
V SC
AV ER OM
AI SIO PL
LA N IA
BL S NT
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TISP3240F3, TISP3260F3,
TISP3290F3,TISP3320F3,TISP3380F3
HIGH-VOLTAGE DUAL BIDIRECTIONAL THYRISTOR
OVERVOLTAGE PROTECTORS
TISP3xxxF3 (HV) Overvoltage Protector Series
Ion-Implanted Breakdown Region
Precise and Stable Voltage
Low Voltage Overshoot under Surge
DEVICE
‘3240F3
‘3260F3
‘3290F3
‘3320F3
‘3380F3
D Package (Top View)
T
1
8
G
VDRM
V(BO)
NC
2
7
G
V
180
200
220
240
270
V
240
260
290
320
380
NC
3
6
G
R
4
5
G
NC - No internal connection
SL Package (Top View)
Planar Passivated Junctions
Low Off-State Current <10 µA
Rated for International Surge Wave Shapes
Waveshape
Standard
2/10 µs
8/20 µs
10/160 µs
GR-1089-CORE
IEC 61000-4-5
FCC Part 68
ITU-T K.20/21
FCC Part 68
FCC Part 68
GR-1089-CORE
10/700 µs
10/560 µs
10/1000 µs
ITSP
T
1
G
2
R
3
MD1XAB
A
175
120
60
Device Symbol
T
50
45
35
.......................................UL Recognized Component
Description
These high-voltage dual bidirectional thyristor protectors
are designed to protect ground backed ringing central
office, access and customer premise equipment against
overvoltages caused by lightning and a.c. power
disturbances. Offered in five voltage variants to meet
battery and protection requirements, they are guaranteed
to suppress and withstand the listed international lightning
surges in both polarities. Overvoltages are initially clipped
by breakdown clamping until the voltage rises to the
breakover level, which causes the device to switch. The
high crowbar holding current prevents d.c. latchup as the
current subsides.
SD3XAA
G
Terminals T, R and G correspond to the
alternative line designators of A, B and C
How To Order
Device
TISP3xxxF3
R
For Standard
Termination Finish
Order As
For Lead Free
Termination Finish
Order As
Packa ge
Carrier
D, Small-o utline
Tap e And Reeled
TISP3xxxF3DR
TISP3xxxF3DR-S
SL, Single-in-line
Tube
TISP3xxxF3SL
TISP3xxxF3SL-S
Insert xxx value corresponding to protection voltages of 240 through 380
*RoHS Directive 2002/95/EC Jan 27 2003 including Annex
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
TISP3xxxF3 (HV) Overvoltage Protector Series
Description (continued)
These monolithic protection devices are fabricated in ion implanted planar structures to ensure precise and matched breakover control
and are virtually transparent to the system in normal operation.
Absolute Maximum Ratings, TA = 25 °C (Unless Otherwise Noted)
Rating
‘3240F3
‘3260F3
‘3290F3
‘3320F3
‘3380F3
Repetitive peak off-state voltage, 0 °C < TA < 70 °C
Symbol
Value
Unit
VDRM
±180
±200
±220
±240
±270
V
Non-repetitive peak on-state pulse current (see Notes 1 and 2)
1/2 (Gas tube differential transient, 1/2 voltage wave shape)
350
2/10 (Telcordia GR-1089-CORE, 2/10 voltage wave shape)
175
1/20 (ITU-T K.22, 1.2/50 voltage wave shape, 25 Ω resistor)
90
8/20 (IEC 61000-4-5, combination wave generator, 1.2/50 voltage wave shape)
120
10/160 (FCC Part 68, 10/160 voltage wave shape)
60
IPPSM
4/250 (ITU-T K.20/21, 10/700 voltage wave shape, simultaneous)
0.2/310 (CNET I 31-24, 0.5/700 voltage wave shape)
38
5/310 (ITU-T K.20/21, 10/700 voltage wave shape, single)
50
5/320 (FCC Part 68, 9/720 voltage wave shape, single)
50
10/560 (FCC Part 68, 10/560 voltage wave shape)
45
10/1000 (Telcordia GR-1089-CORE, 10/1000 voltage wave shape)
35
Non-repetitive peak on-state current, 0 °C < TA < 70 °C (see Notes 1 and 3)
50 Hz, 1 s
A
55
D Package
SL Package
Initial rate of rise of on-state current, Linear current ramp, Maximum ramp value < 38 A
Junction temperature
Storage temperature range
4.3
7.1
A
diT/dt
250
A/µs
TJ
-65 to +150
°C
Tstg
-65 to +150
°C
ITSM
NOTES: 1. Further details on surge wave shapes are contained in the Applications Information section.
2. Initially, the TISP® device m ust be in thermal equilibrium with 0 °C < TJ <70 °C. The surge may be repeated after the TISP® device
returns to its initial conditions.
3. Above 70 °C, derate linearly to zero at 150 °C lead temperature.
Electrical Characteristics for R and T Terminal Pair, TA = 25 °C (Unless Otherwise Noted)
ID
Parameter
Repetitive peak offstate current
Off-state current
Coff
Off-state capacitance
IDRM
Test Conditions
Min
Typ
Max
Unit
VD = ±2VDRM, 0 °C < TA < 70 °C
±10
µA
VD = ±50 V
f = 100 kHz, Vd = 100 mV , VD = 0,
Third terminal voltage = -50 V to +50 V
(see Notes 4 and 5)
±10
µA
D Package
0.05
0.15
SL Package
0.03
0.1
pF
NOTES: 4. These capacitance measurements employ a three terminal capacitance bridge incorporating a guard circuit. The third terminal is
connected to the guard terminal of the bridge.
5. Further details on capacitance are given in the Applications Information section.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
TISP3xxxF3 (HV) Overvoltage Protector Series
Electrical Characteristics for T and G or R and G Terminals, TA = 25 °C (Unless Otherwise Noted)
IDRM
V(BO)
V(BO)
I(BO)
VT
IH
dv/dt
ID
Coff
Parameter
Repetitive peak offstate current
Test Conditions
dv/dt = ±250 V/ms, RSOURCE = 300 Ω
Impulse breakover
voltage
dv/dt ≤ ±1000 V/µs, Linear voltage ramp,
Maximum ramp value = ±500 V
RSOURCE = 50 Ω
Off-state capacitance
Typ
VD = ±VDRM, 0 °C < TA < 70 °C
Breakover voltage
Breakover current
On-state voltage
Holding current
Critical rate of rise of
off-state voltage
Off-state current
Min
‘3240F3
‘3260F3
‘3290F3
‘3320F3
‘3380F3
‘3240F3
‘3260F3
‘3290F3
‘3320F3
‘3380F3
dv/dt = ±250 V/ms, RSOURCE = 300 Ω
IT = ±5 A, tW = 100 µs
IT = ±5 A, di/dt = -/+30 mA/ms
Unit
±10
µA
±240
±260
±290
±320
±380
V
±267
±287
±317
±347
±407
V
±0.15
A
V
A
±5
kV/µs
±0.1
Linear voltage ramp, Maximum ramp value < 0.85VDRM
Max
VD = ±50 V
f = 1 MHz, Vd = 0.1 V r.m.s., VD = 0
f = 1 MHz, Vd = 0.1 V r.m.s., VD = -5 V
f = 1 MHz, Vd = 0.1 V r.m.s., VD = -50 V
(see Notes 5 and 6)
±0.6
±3
57
26
11
±10
95
45
20
µA
pF
NOTES: 6 These capacitance measurements employ a three terminal capacitance bridge incorporating a guard circuit. The third terminal is
connected to the guard terminal of the bridge.
7. Further details on capacitance are given in the Applications Information section.
Thermal Characteristics
Parameter
RθJA
Junction to free air thermal resistance
Min
Test Conditions
Ptot = 0.8 W, TA = 25 °C
5 cm2, FR4 PCB
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
Typ
Max
D Package
160
SL Package
135
Unit
°C/W
TISP3xxxF3 (HV) Overvoltage Protector Series
Parameter Measurement Information
+i
Quadrant I
ITSP
Switching
Characteristic
ITSM
IT
V(BO)
VT
I(BO)
IH
V(BR)M
VDRM
-v
I(BR)
V(BR)
I(BR)
IDRM
ID
VD
ID
VD
IDRM
+v
VDRM
V(BR)M
V(BR)
IH
I(BO)
V(BO)
VT
IT
ITSM
Quadrant III
Switching
Characteristic
ITSP
-i
PMXXAA
Figure 1. Voltage-Current Characteristics for any Terminal Pair
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
TISP3xxxF3 (HV) Overvoltage Protector Series
Typical Characteristics - R and G or T and G Terminals
OFF-STATE CURRENT
vs
JUNCTION TEMPERATURE
100
NORMALIZED BREAKDOWN VOLTAGES
vs
JUNCTION TEMPERATURE
TC3HAI
TC3HAF
Normalized Breakdown Voltages
1.2
10
1
VD = 50 V
0.1
VD = -50 V
0.01
V(BO)
1.1
V(BR)M
1.0
V(BR)
Normalized to V(BR)
I(BR) = 100 µA and 25 °C
Positive Polarity
0.001
0.9
-25
0
25
50
75
100
125
150
-25
TJ - Junction Temperature - °C
0
25
50
75
100
125
150
TJ - Junction Temperature - °C
Figure 2.
Figure 3.
NORMALIZED BREAKDOWN VOLTAGES
vs
JUNCTION TEMPERATURE
TC3HAJ
OFF-STATE CURRENT
vs
ON-STATE VOLTAGE
100
TC3HAL
V(BO)
1.1
IT - On-State Current - A
Normalized Breakdown Voltages
1.2
V(BR)M
1.0
V(BR)
10
150 °C
Normalized to V(BR)
25 °C
I(BR) = 100 µA and 25 °C
-40 °C
Negative Polarity
0.9
1
-25
0
25
50
75
100
125
TJ - Junction Temperature - °C
Figure 4.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
150
1
2
3
4
5
VT - On-State Voltage - V
Figure 5.
6
7 8 9 10
TISP3xxxF3 (HV) Overvoltage Protector Series
1.0
0.9
0.8
0.7
HOLDING CURRENT & BREAKDOWN CURRENT
vs
TC3HAH
JUNCTION TEMPERATURE
NORMALIZED BREAKOVER VOLTAGES
vs
JUNCTION TEMPERATURE
TC3HAB
1.3
0.5
Normalized Breakover Voltage
0.6
I(BO)
0.4
0.3
IH
0.2
1.2
1.1
Positive
Negative
0.1
0
25
50
75
100
125
1.0
0·001
150
0·1
1
10
100
di/dt - Rate of Rise of Principle Current - A/µs
Figure 6.
Figure 7.
OFF-STATE CAPACITANCE
vs
TERMINAL VOLTAGE
100
OFF-STATE CAPACITANCE
vs
JUNCTION TEMPERATURE
TC3HAE
Positive Bias
Negative Bias
10
0·1
0·01
TJ - Junction Temperature - °C
500
Off-State Capacitance - pF
-25
Off-State Capacitance - pF
IH, I(BO) - Holding Current, Breakover Current - A
Typical Characteristics - R and G or T and G Terminals
TC3HAD
100
Terminal Bias = 0
Terminal Bias = 50 V
10
Terminal Bias = -50 V
1
1
Terminal Voltage - V
Figure 8.
10
50
-25
0
25
50
75
100
125
150
TJ - Junction Temperature - °C
Figure 9.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
TISP3xxxF3 (HV) Overvoltage Protector Series
Typical Characteristics - R and G or T and G Terminals
SURGE CURRENT
vs
DECAY TIME
Maximum Surge Current - A
1000
TC3HAA
100
10
2
10
100
Decay Time - µs
Figure 10.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
1000
TISP3xxxF3 (HV) Overvoltage Protector Series
Typical Characteristics - R and T Terminals
OFF-STATE CURRENT
vs
JUNCTION TEMPERATURE
100
NORMALIZED BREAKDOWN VOLTAGES
vs
JUNCTION TEMPERATURE
TC3HAK
TC3HAG
Normalized Breakdown Voltages
VD = ±50 V
ID - Off-State Current - µA
10
1
0·1
0·01
1.2
V(BO)
1.1
V(BR)M
1.0
V(BR)
Normalized to V(BR)
I(BR) = 100 µA and 25 °C
Both Polarities
0·001
0.9
-25
0
25
50
75
100
125
150
-25
TJ - Junction Temperature - °C
50
75
100
125
150
Figure 12.
NORMALIZED BREAKOVER VOLTAGES
vs
RATE OF RISE OF PRINCIPLE CURRENT
TC3HAC
100
90
80
70
OFF-STATE CAPACITANCE
vs
TERMINAL VOLTAGE
60
Off-State Capacitance - fF
Normalized Breakover Voltage
25
TJ - Junction Temperature - °C
Figure 11.
1.3
0
1.2
1.1
TC3XAA
D Package
50
40
SL Package
30
20
Both Voltage Polarities
1.0
0·001
0·01
0·1
1
10
di/dt - Rate of Rise of Principle Current - A/µs
Figure 13.
100
10
0·1
1
10
50
Terminal Voltage - V
Figure 14.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
TISP3xxxF3 (HV) Overvoltage Protector Series
Thermal Information
THERMAL RESPONSE
TI3MAA
VGEN = 350 Vrms
ZθJA - Transient Thermal Impedance - °C/W
ITRMS - Maximum Non-Recurrent 50 Hz Current - A
MAXIMUM NON-RECURRING 50 Hz CURRENT
vs
CURRENT DURATION
TI3HAA
RGEN = 20 to 250 Ω
10
SL Package
D Package
1
0.1
1
10
100
t - Current Duration - s
Figure 15.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
1000
100
D Package
SL Package
10
1
0·0001 0·001
0·01
0·1
1
10
t - Power Pulse Duration - s
Figure 16.
100
1000
TISP3xxxF3 (HV) Overvoltage Protector Series
APPLICATIONS INFORMATION
Electrical Characteristics
The electrical characteristics of a TISP® device are strongly dependent on junction temperature, TJ. Hence, a characteristic value will
depend on the junction temperature at the instant of measurement. The values given in this data sheet were measured on commercial
testers, which generally minimize the temperature rise caused by testing. Application values may be calculated from the parameters’
temperature coefficient, the power dissipated and the thermal response curve, Zθ (see M. J. Maytum, “Transient Suppressor Dynamic
Parameters.” TI Technical Journal, vol. 6, No. 4, pp. 63-70, July-August 1989).
Lightning Surge
Wave Shape Notation
Most lightning tests, used for equipment verification, specify a unidirectional sawtooth waveform which has an exponential rise and an
exponential decay. Wave shapes are classified in terms of peak amplitude (voltage or current), rise time and a decay time to 50 % of
the maximum amplitude. The notation used for the wave shape is amplitude, rise time/decay time. A 50 A, 5/310 µs wave shape would
have a peak current value of 50 A, a rise time of 5 µs and a decay time of 310 µs. The TISP® surge current graph comprehends the
wave shapes of commonly used surges.
Generators
There are three categories of surge generator type, single wave shape, combination wave shape and circuit defined. Single wave shape
generators have essentially the same wave shape for the open circuit voltage and short circuit current (e.g. 10/1000 µs open circuit
voltage and short circuit current). Combination generators have two wave shapes, one for the open circuit voltage and the other for the
short circuit current (e.g. 1.2/50 µs open circuit voltage and 8/20 µs short circuit current). Circuit specified generators usually equate to
a combination generator, although typically only the open circuit voltage waveshape is referenced (e.g. a 10/700 µs open circuit voltage
generator typically produces a 5/310 µs short circuit current). If the combination or circuit defined generators operate into a finite resistance, the wave shape produced is intermediate between the open circuit and short circuit values.
Current Rating
When the TISP® device switches into the on-state it has a very low impedance. As a result, although the surge wave shape may be
defined in terms of open circuit voltage, it is the current wave shape that must be used to assess the required TISP® surge capability.
As an example, the ITU-T K.21 1.5 kV, 10/700 µs open circuit voltage surge is changed to a 38 A, 5/310 µs current waveshape when
driving into a short circuit. Thus, the TISP® surge current capability, when directly connected to the generator, will be found for the
ITU-T K.21 waveform at 310 µs on the surge graph and not 700 µs. Some common short circuit equivalents are tabulated below:
Standard
Open Circuit Voltage Short Circuit Current
ITU-T K.21
1.5 kV, 10/700 µs
37.5 A, 5/310 µs
ITU-T K.20
1 kV, 10/700 µs
25 A, 5/310 µs
IEC 61000-4-5, combination wave generator
1.0 kV, 1.2/50 µs
500 A, 8/20 µs
Telcordia GR-1089-CORE
1.0 kV, 10/1000 µs
100 A, 10/1000 µs
Telcordia GR-1089-CORE
2.5 kV, 2/10 µs
500 A, 2/10 µs
FCC Part 68, Type A
1.5 kV, <10/>160 µs
200 A,<10/>160 µs
FCC Part 68,Type A
800 V, <10/>560 µs
100 A,<10/>160 µs
FCC Part 68, Type B
1.5 kV, 9/720 µs
37.5 A, 5/320 µs
Any series resistance in the protected equipment will reduce the peak circuit current to less than the generators’ short circuit value.
A 1 kV open circuit voltage, 100 A short circuit current generator has an effective output impedance of 10 Ω (1000/100). If the
equipment has a series resistance of 25 Ω, then the surge current requirement of the TISP® device becomes 29 A (1000/35) and not
100 A.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
TISP3xxxF3 (HV) Overvoltage Protector Series
APPLICATIONS INFORMATION
Protection Voltage
The protection voltage, (V(BO)), increases under lightning surge conditions due to thyristor regeneration. This increase is dependent on
the rate of current rise, di/dt, when the TISP® device is clamping the voltage in its breakdown region. The V(BO) value under surge
conditions can be estimated by multiplying the 50 Hz rate V(BO) (250 V/ms) value by the normalized increase at the surge’s di/dt (Figure
7 ). An estimate of the di/dt can be made from the surge generator voltage rate of rise, dv/dt, and the circuit resistance.
As an example, the ITU-T K.21 1.5 kV, 10/700 µs surge has an average dv/dt of 150 V/µs, but, as the rise is exponential, the initial dv/dt
is higher, being in the region of 450 V/µs. The instantaneous generator output resistance is 25 Ω. If the equipment has an additional
series resistance of 20 Ω, the total series resistance becomes 45 Ω. The maximum di/dt then can be estimated as 450/45 = 10 A/µs. In
practice, the measured di/dt and protection voltage increase will be lower due to inductive effects and the finite slope resistance of the
TISP® breakdown region.
Capacitance
Off-state Capacitance
The off-state capacitance of a TISP® device is sensitive to junction temperature, TJ, and the bias voltage, comprising of the d.c. voltage,
VD, and the a.c. voltage, Vd. All the capacitance values in this data sheet are measured with an a.c. voltage of 100 mV. The typical 25 °C
variation of capacitance value with a.c. bias is shown in Figure 17. When VD >> Vd, the capacitance value is independent on the value of
Vd. The capacitance is essentially constant over the range of normal telecommunication frequencies.
NORMALIZED CAPACITANCE
vs
RMS AC TEST VOLTAGE
1.05
AIXXAA
Normalized Capacitance
1.00
0.95
0.90
0.85
0.80
Normalized to V d = 100 mV
0.75
DC Bias, VD = 0
0.70
1
10
100
Vd - RMS AC Test Voltage - mV
Figure 17.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.
1000
TISP3xxxF3 (HV) Overvoltage Protector Series
APPLICATIONS INFORMATION
Longitudinal Balance
Figure 18 shows a three terminal TISP® device with its equivalent “delta” capacitance. Each capacitance, CTG, CRG and CTR, is the true
terminal pair capacitance measured with a three terminal or guarded capacitance bridge. If wire R is biased at a larger potential than
wire T, then CTG >CRG. Capacitance CTG is equivalent to a capacitance of CRG in parallel with the capacitive difference of (CTG -CRG).
The line capacitive unbalance is due to (CTG -CRG) and the capacitance shunting the line is CTR +CRG/2.
All capacitance measurements in this data sheet are three terminal guarded to allow the designer to accurately assess capacitive
unbalance effects. Simple two terminal capacitance meters (unguarded third terminal) give false readings as the shunt capacitance via
the third terminal is included.
T
T
(CTG -CRG )
CTG
CRG
Equipment
G
Equipment
G
CTR
CTR
CRG
CRG
R
AIXXAB
R
CTG > CRG
Equivalent Unbalance
Figure 18.
“TISP” is a trademark of Bourns, Ltd., a Bourns Company, and is Registered in U.S. Patent and Trademark Office.
“Bourns” is a registered trademark of Bourns, Inc. in the U.S. and other countries.
MARCH 1994 - REVISED MARCH 2006
Specifications are subject to change without notice.
Customers should verify actual device performance in their specific applications.