R0633YS10D [LITTELFUSE]
Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1000V V(DRM), 1000V V(RRM), 1 Element, 101A335, 3 PIN;![R0633YS10D](http://pdffile.icpdf.com/pdf2/p00293/img/icpdf/R0633YS12D_1777582_icpdf.jpg)
型号: | R0633YS10D |
厂家: | ![]() |
描述: | Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1000V V(DRM), 1000V V(RRM), 1 Element, 101A335, 3 PIN 栅 栅极 |
文件: | 总12页 (文件大小:349K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
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Date:- 25 Jun, 2001
Data Sheet Issue:- 2
WESTCODE
Distributed Gate Thyristor
Types R0633YS10x to R0633YS12x
Absolute Maximum Ratings
MAXIMUM
LIMITS
VOLTAGE RATINGS
UNITS
VDRM
VDSM
VRRM
VRSM
Repetitive peak off-state voltage, (note 1)
Non-repetitive peak off-state voltage, (note 1)
Repetitive peak reverse voltage, (note 1)
Non-repetitive peak reverse voltage, (note 1)
1000-1200
V
V
V
V
1000-1200
1000-1200
1100-1300
MAXIMUM
LIMITS
633
OTHER RATINGS
UNITS
IT(AV)
IT(AV)
IT(AV)
IT(RMS)
IT(d.c.)
ITSM
ITSM2
I2t
Mean on-state current, Tsink=55°C, (note 2)
Mean on-state current. Tsink=85°C, (note 2)
Mean on-state current. Tsink=85°C, (note 3)
Nominal RMS on-state current, Tsink=25°C, (note 2)
D.C. on-state current, Tsink=25°C, (note 4)
A
A
A
A
A
423
246
1269
1055
6.3
Peak non-repetitive surge tp=10ms, VRM=0.6VRRM, (note 5)
kA
kA
A2s
A2s
A/µs
A/µs
V
W
W
V
≤
6.9
Peak non-repetitive surge tp=10ms, VRM 10V, (note 5)
I2t capacity for fusing tp=10ms, VRM=0.6VRRM, (note 5)
200×103
240×103
500
I2t
≤
I2t capacity for fusing tp=10ms, VRM 10V, (note 5)
Maximum rate of rise of on-state current (repetitive), (Note 6)
Maximum rate of rise of on-state current (non-repetitive), (Note 6)
Peak reverse gate voltage
Mean forward gate power
Peak forward gate power
Non-trigger gate voltage, (Note 7)
Operating temperature range
Storage temperature range
diT/dt
1000
5
2
30
0.25
VRGM
PG(AV)
PGM
VGD
THS
Tstg
-40 to +125
-40 to +150
°C
°C
Notes:-
1) De-rating factor of 0.13% per °C is applicable for Tj below 25°C.
2) Double side cooled, single phase; 50Hz, 180° half-sinewave.
3) Single side cooled, single phase; 50Hz, 180° half-sinewave.
4) Double side cooled.
5) Half-sinewave, 125°C Tj initial.
≤
6) VD=67% VDRM, IFG=2A, tr 0.5µs, Tcase=125°C.
7) Rated VDRM
.
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 1 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Characteristics
PARAMETER
MIN.
TYP. MAX. TEST CONDITIONS
UNITS
(Note 1)
VTM
V0
Maximum peak on-state voltage
Threshold voltage
-
-
1.85 ITM=1000A
V
V
-
-
1.25
rS
Slope resistance
-
-
0.614
Ω
m
dv/dt Critical rate of rise of off-state voltage
200
-
-
VD=80% VDRM, linear ramp
µ
V/ s
IDRM
IRRM
VGT
IGT
IH
Peak off-state current
Peak reverse current
Gate trigger voltage
Gate trigger current
-
-
-
-
-
-
-
-
-
-
-
60
60
3.0
Rated VDRM
Rated VRRM
Tj=25°C
mA
mA
V
-
-
200 Tj=25°C
VD=10V, IT=3A
mA
mA
µC
µC
A
Holding current
-
1000 Tj=25°C
Qrr
Qra
Irm
Recovered charge
125
85
65
2.25
-
Recovered charge, 50% Chord
Reverse recovery current
Reverse recovery time
100
I
TM=550A, tp=500µs, di/dt=40A/µs, Vr=50V
-
-
trr
µs
ITM=550A, tp=500µs, di/dt=40A/µs, Vr=50V,
Vdr=80%VDRM, dVdr/dt=20V/µs
-
-
-
28
30
tq
Turn-off time
µs
ITM=550A, tp=500µs, di/dt=40A/µs, Vr=50V,
20
Vdr=80%VDRM, dVdr/dt=200V/µs
-
-
-
-
0.050 Double side cooled
K/W
K/W
kN
Rth(j-hs) Thermal resistance, junction to heatsink
0.10 Single side cooled
F
Mounting force
Weight
5.5
-
-
10
-
Wt
90
g
Notes:-
1) Unless otherwise indicated Tj=125°C.
2) The required tq (specified with dVdr/dt=200V/µs) is represented by an ‘x’ in the device part number. See ordering information
for details of tq codes.
Introduction
The R0633 series of Distributed Gate thyristors have fast switching characteristics provided by a
regenerative, interdigitated gate. They also exhibit low switching losses. They are therefore suitable for
medium current, medium frequency applications.
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 2 of 12
June, 2001
WESTCODE Positive development in power electronics
Notes on Ratings and Characteristics
1.0 Voltage Grade Table
R0663YS10x to R0633YS12x
V
DRM VDSM VRRM
VRSM
V
VD VR
DC V
700
Voltage Grade
V
10
12
1000
1200
1100
1300
810
2.0 Extension of Voltage Grades
This report is applicable to other and higher voltage grades when supply has been agreed by
Sales/Production.
3.0 Extension of Turn-off Time
This Report is applicable to other tq/re-applied dv/dt combinations when supply has been agreed by
Sales/Production.
4.0 Repetitive dv/dt
Higher dv/dt selections are available up to 1000V/µs on request.
5.0 De-rating Factor
A blocking voltage de-rating factor of 0.13%/°C is applicable to this device for Tj below 25oC.
6.0 Rate of rise of on-state current
The maximum un-primed rate of rise of on-state current must not exceed 1500A/µs at any time during
turn-on on a non-repetitive basis. For repetitive performance, the on-state rate of rise of current must not
exceed 1000A/µs at any time during turn-on. Note that these values of rate of rise of current apply to the
total device current including that from any local snubber network.
7.0 Square wave ratings
These ratings are given for load component rate of rise of forward current of 100 and 500 A/µs.
8.0 Duty cycle lines
The 100% duty cycle is represented on all the ratings by a straight line. Other duties can be included as
parallel to the first.
9.0 Maximum Operating Frequency
The maximum operating frequency is set by the on-state duty, the time required for the thyristor to turn off
(tq) and for the off-state voltage to reach full value (tv), i.e.
1
max =
f
tpulse +tq +tv
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 3 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
10.0 On-State Energy per Pulse Characteristics
These curves enable rapid estimation of device dissipation to be obtained for conditions not covered by
the frequency ratings.
Let Ep be the Energy per pulse for a given current and pulse width, in joules
Let Rth(J-Hs) be the steady-state d.c. thermal resistance (junction to sink)
and TSINK be the heat sink temperature.
Then the average dissipation will be:
= ⋅
=
−
⋅
WAV EP f and TSINK (max.) 125 WAV Rth
(
J −Hs
)
11.0 Reverse recovery ratings
(i) Qra is based on 50% Irm chord as shown in Fig. 1 below.
Fig. 1
µ
(ii) Qrr is based on a 150 s integration time.
150µs
Qrr = irr .dt
∫
i.e.
0
t1
t2
K Factor =
(iii)
12.0 Reverse Recovery Loss
12.1 Determination by Measurement
From waveforms of recovery current obtained from a high frequency shunt (see Note 1, Page 5) and
reverse voltage present during recovery, an instantaneous reverse recovery loss waveform must be
constructed. Let the area under this waveform be E joules per pulse. A new heat sink temperature can
then be evaluated from:
=
− ⋅
+ ⋅
TSINK (new) TSINK (original) E k f Rth
(
J −Hs
)
where k = 0.227 (°C/W)/s
E = Area under reverse loss waveform per pulse in joules (W.s.)
f = rated frequency Hz at the original heat sink temperature.
Rth(J-Hs) = d.c. thermal resistance (°C/W).
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 4 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
The total dissipation is now given by:
=
+ ⋅
E f
W(TOT) W(original)
12.2 Determination without Measurement
In circumstances where it is not possible to measure voltage and current conditions, or for design
purposes, the additional losses E in joules may be estimated as follows.
Let E be the value of energy per reverse cycle in joules (curves in Figure 9).
Let f be the operating frequency in Hz
TSINK
=
TSINK
(
E Rth f
− ⋅ ⋅
)
(
new
)
( )
original
Where TSINK (new) is the required maximum heat sink temperature and
TSINK (original) is the heat sink temperature given with the frequency ratings.
A suitable R-C snubber network is connected across the thyristor to restrict the transient reverse voltage
to a peak value (Vrm) of 67% of the maximum grade. If a different grade is being used or Vrm is other than
67% of Grade, the reverse loss may be approximated by a pro rata adjustment of the maximum value
obtained from the curves.
NOTE 1
- Reverse Recovery Loss by Measurement
This thyristor has a low reverse recovered charge and peak reverse recovery current. When measuring
the charge care must be taken to ensure that:
(a) a.c. coupled devices such as current transformers are not affected by prior passage of high
amplitude forward current.
(b) A suitable, polarised, clipping circuit must be connected to the input of the measuring oscilloscope
to avoid overloading the internal amplifiers by the relatively high amplitude forward current signal
(c) Measurement of reverse recovery waveform should be carried out with an appropriate critically
damped snubber, connected across diode anode to cathode. The formula used for the calculation
of this snubber is shown below:
Vr
R2 = 4⋅
CS ⋅ di
dt
Where: Vr = Commutating source voltage
CS = Snubber capacitance
R
= Snubber resistance
13.0 Gate Drive
Ω
The recommended pulse gate drive is 30V, 15 with a short-circuit current rise time of not more than
0.5µs. This gate drive must be applied when using the full di/dt capability of the device.
The duration of pulse may need to be configured with respect to the application but should be no shorter
than 20µs, otherwise an increase in pulse current could be needed to supply the resulting increase in
charge to trigger.
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 5 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
14.0 Computer Modelling Parameters
14.1 Calculating VT using ABCD Coefficients
The on-state characteristic IT vs VT, on page 7 is represented in two ways;
(i)
the well established Vo and rs tangent used for rating purposes and
(ii)
a set of constants A, B, C, D, forming the coefficients of the representative equation for VT in
terms of IT given below:
= + ⋅ ( )+ ⋅ + ⋅
VT A B ln IT C IT D IT
The constants, derived by curve fitting software, are given in this report for hot and cold characteristics
where possible. The resulting values for VT agree with the true device characteristic over a current range,
which is limited to that plotted.
25°C Coefficients
125°C Coefficients
A
B
C
D
1.806168
0.0343271
7.9919×10-4
-0.0267678
A
B
C
D
2.770221
-0.3652107
3.8581×10-4
0.03847728
14.2 D.C. Thermal Impedance Calculation
−
τ p
t
=
p n
r = r ⋅ 1− e
∑
t
p
=
p 1
Where p = 1 to n, n is the number of terms in the series.
t = Duration of heating pulse in seconds.
rt = Thermal resistance at time t.
rp = Amplitude of pth term.
τp
= Time Constant of rth term.
D.C. Double Side Cooled
Term
rp
τp
1
2
3
4
0.0200056
0.3391689
9.923438×10-3
0.1269073
0.01433715
0.03562131
4.284403×10-3
2.562946×10-3
D.C. Single Side Cooled
Term
rp
τp
1
2
3
4
5
0.06157697
2.136132
8.431182×10-3
1.212898
0.01031315
0.1512408
0.01613806
0.04244
5.181088×10-3
2.889595×10-3
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 6 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Curves
Figure 1 - On-state characteristics of Limit device
Figure 2 - Transient thermal impedance
10000
1
SSC 0.1K/W
0.1
DSC 0.05K/W
1000
0.01
0.001
Tj = 25°C
Tj = 125°C
R0633YS10x-12x
Issue 2
R0633YS10x-12x
Issue 2
100
0.0001
0
1
2
3
4
0.0001
0.001
0.01
0.1
1
10
100
Instantaneous on-state voltage - VT (V)
Time (s)
Figure 3 - Gate characteristics - Trigger limits
Figure 4 - Gate characteristics - Power curves
20
8
R0633YS10x-12x
Issue 2
R0633YS10x-12x
Issue 2
Tj=25°C
7
Tj=25°C
18
Max VG dc
16
6
14
12
10
8
Max VG dc
5
4
3
2
1
0
IGT, VGT
PG Max 30W dc
6
4
PG 2W dc
2
Min VG dc
0.5
Min VG dc
IGD, VGD
0.1
0
0
2
4
6
8
10
0
0.2
0.3
0.4
0.6
Gate Trigger Current - IGT (A)
Gate Trigger Current - IGT (A)
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 7 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Figure 5 - Total recovered charge, Qrr
Figure 6 - Recovered charge, Qra (50% chord)
1000
100
10
1000
2000A
1500A
1000A
500A
2000A
1500A
1000A
500A
100
Tj = 125°C
Tj = 125°C
R0633YS10x-12x
R0633YS10x-12x
Issue 2
Issue 2
10
10
100
Commutation rate - di/dt (A/µs)
1000
10
100
Commutation rate - di/dt (A/µs)
1000
Figure 7 - Peak reverse recovery current, Irm
Figure 8 - Maximum recovery time, trr (50% chord)
10
1000
2000A
1500A
1000A
500A
100
2000A
1500A
1000A
500A
Tj = 125°C
Tj = 125°C
R0633YS10x-12x
Issue 2
R0633YS10x-12x
Issue 2
1
10
10
100
1000
10
100
Commutation rate - di/dt (A/µs)
1000
Commutation rate - di/dt (A/µs)
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 8 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Figure 9 - Reverse recovery energy per pulse
Figure 10 - Sine wave energy per pulse
1.00E+02
1.00E+01
1.00E+00
1.00E-01
1.00E-02
10
R0633YS10x-12x
Issue 2
Tj=125°C
2000A
1000A
750A
3kA
2kA
400A
1.5kA
1kA
Snubber Value
with 0.22µF, 5Ω
500A
250A
Tj = 125°C
Vrm = 67% VRRM
R0633YS10x-12x
Issue 2
1
1.00E-05
1.00E-04
1.00E-03
1.00E-02
1
10
100
1000
Pulse width (s)
Commutation rate - di/dt (A/µs)
Figure 11 - Sine wave frequency ratings
Figure 12 - Sine wave frequency ratings
1.00E+05
1.00E+05
R0633YS10x-12x
Issue 2
THs=55°C
100% Duty Cycle
250A
100% Duty Cycle
500A
1kA
1.00E+04
1.00E+03
1.00E+02
1.00E+01
1.00E+04
500A
1kA
1.5kA
2kA
1.5kA
1.00E+03
2kA
3kA
3kA
1.00E+02
THs=85°C
R0633YS10x-12x
Issue 2
1.00E+01
1.00E-05
1.00E-04
1.00E-03
1.00E-02
1.00E-05
1.00E-04
1.00E-03
1.00E-02
Pulse Width (s)
Pulse width (s)
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 9 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Figure 13 - Square wave frequency ratings
Figure 14 - Square wave frequency ratings
1.00E+05
1.00E+05
1.00E+04
1.00E+03
1.00E+02
1.00E+01
1.00E+00
250A
250A
500A
100% Duty Cycle
1.00E+04
100% Duty Cycle
1kA
500A
1.5kA
1kA
1.5kA
2kA
2kA
1.00E+03
3kA
1.00E+02
3kA
1.00E+01
THs=55°C
THs=55°C
di/dt=100A/µs
di/dt=500A/µs
R0633YS10x-12x
Issue 2
R0633YS10x-12x
Issue 2
1.00E+00
1.00E-05
1.00E-04
1.00E-03
1.00E-02
1.00E-05
1.00E-04
1.00E-03
1.00E-02
Pulse width (s)
Pulse width (s)
Figure 15 - Square wave frequency ratings
Figure 16 - Square wave frequency ratings
1.00E+05
1.00E+05
R0633YS10x-12x
Issue 2
di/dt=500A/µs
THs=85°C
250A
500A
250A
1.00E+04
1.00E+03
1.00E+02
1.00E+01
1.00E+00
100% Duty Cycle
100% Duty Cycle
1.00E+04
500A
1kA
1kA
1.5kA
1.5kA
1.00E+03
2kA
3kA
2kA
3kA
1.00E+02
THs=85°C
di/dt=100A/µs
R0633YS10x-12x
Issue 2
1.00E+01
1.00E-05
1.00E-04
1.00E-03
1.00E-02
1.00E-05
1.00E-04
1.00E-03
1.00E-02
Pulse width (s)
Pulse width (s)
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 10 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Figure 17 - Square wave energy per pulse
Figure 18 - Square wave energy per pulse
1.00E+02
1.00E+02
1.00E+01
1.00E+00
1.00E-01
1.00E-02
R0633YS10x-12x
Issue 2
di/dt=500A/µs
R0633YS10x-12x
Issue 2
di/dt=100A/µs
Tj=125°C
Tj=125°C
3kA
2kA
1.5kA
1.00E+01
3kA
2kA
1.00E+00
1.00E-01
1.00E-02
1.5kA
1kA
1kA
500A
250A
500A
250A
1.00E-05
1.00E-04
1.00E-03
1.00E-02
1.00E-05
1.00E-04
1.00E-03
1.00E-02
Pulse width (s)
Pulse width (s)
Figure 19 - Maximum surge and I2t Ratings
Gate may temporarily lose control of conduction angle
100000
10000
1000
1.00E+07
R0633YS10x-12x
Issue 2
Tj (initial) = 125°C
I2t: VRRM≤10V
I2t: 60% VRRM
1.00E+06
1.00E+05
ITSM: VRRM≤10V
ITSM: 60% VRRM
1
3
5
10
10
50 100
1
5
Duration of surge (cycles @ 50Hz)
Duration of surge (ms)
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 11 of 12
June, 2001
WESTCODE Positive development in power electronics
R0663YS10x to R0633YS12x
Outline Drawing & Ordering Information
ORDERING INFORMATION
(Please quote 10 digit code as below)
R
0633
YS
♦ ♦
♦
Fixed
Fixed
Fixed
Off-State Voltage
Code
tq Code
D=20µs, E=25µs,
F=30µs
Type Code
Outline Code
Outline code
VDRM/100
10-12
Typical order code: R0633YS12D – 1.2kV VDRM, 20µs tq, 15.1mm clamp height capsule.
UK: Westcode Semiconductors Ltd.
P.O. Box 57, Chippenham, Wiltshire, England. SN15 1JL.
Tel: +44 (0) 1249 444524 Fax: +44 (0) 1249 659448
E-Mail: WSL.sales@westcode.com
WESTCODE
USA: Westcode Semiconductors Inc.
3270 Cherry Avenue, Long Beach, California 90807
Tel: 562 595 6971 Fax: 562 595 8182
Internet: http://www.westcode.com
E-Mail: WSI.sales@westcode.com
The information contained herein is confidential and is protected by Copyright. The information may not be used or disclosed
except with the written permission of and in the manner permitted by the proprietors Westcode Semiconductors Ltd.
© Westcode Semiconductors Ltd.
In the interest of product improvement, Westcode reserves the right to change specifications at any time without prior notice.
Devices with a suffix code (2-letter or letter/digit/letter combination) added to their generic code are not necessarily subject to
the conditions and limits contained in this report.
Data Sheet. Types R0633YS10x to R0633YS12x Issue 2
Page 12 of 12
June, 2001
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Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1000V V(DRM), 1000V V(RRM), 1 Element, 101A335, 3 PIN
LITTELFUSE
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Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1000V V(DRM), 1000V V(RRM), 1 Element, 101A335, 3 PIN
IXYS
![](http://pdffile.icpdf.com/pdf2/p00293/img/page/R0633YS12D_1777582_files/R0633YS12D_1777582_1.jpg)
![](http://pdffile.icpdf.com/pdf2/p00293/img/page/R0633YS12D_1777582_files/R0633YS12D_1777582_2.jpg)
R0633YS10F
Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1000V V(DRM), 1000V V(RRM), 1 Element, 101A335, 3 PIN
LITTELFUSE
![](http://pdffile.icpdf.com/pdf2/p00261/img/page/R0633YS10D_1574913_files/R0633YS10D_1574913_1.jpg)
![](http://pdffile.icpdf.com/pdf2/p00261/img/page/R0633YS10D_1574913_files/R0633YS10D_1574913_2.jpg)
R0633YS12D
Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1200V V(DRM), 1200V V(RRM), 1 Element, 101A335, 3 PIN
IXYS
![](http://pdffile.icpdf.com/pdf2/p00293/img/page/R0633YS12D_1777582_files/R0633YS12D_1777582_1.jpg)
![](http://pdffile.icpdf.com/pdf2/p00293/img/page/R0633YS12D_1777582_files/R0633YS12D_1777582_2.jpg)
R0633YS12D
Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1200V V(DRM), 1200V V(RRM), 1 Element, 101A335, 3 PIN
LITTELFUSE
![](http://pdffile.icpdf.com/pdf2/p00261/img/page/R0633YS10D_1574913_files/R0633YS10D_1574913_1.jpg)
![](http://pdffile.icpdf.com/pdf2/p00261/img/page/R0633YS10D_1574913_files/R0633YS10D_1574913_2.jpg)
R0633YS12F
Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1200V V(DRM), 1200V V(RRM), 1 Element, 101A335, 3 PIN
IXYS
![](http://pdffile.icpdf.com/pdf2/p00293/img/page/R0633YS12D_1777582_files/R0633YS12D_1777582_1.jpg)
![](http://pdffile.icpdf.com/pdf2/p00293/img/page/R0633YS12D_1777582_files/R0633YS12D_1777582_2.jpg)
R0633YS12F
Silicon Controlled Rectifier, 1269A I(T)RMS, 1055000mA I(T), 1200V V(DRM), 1200V V(RRM), 1 Element, 101A335, 3 PIN
LITTELFUSE
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