G1
K1
G2
K2
D
N
E
K
G
C
H
M
B
B
E
F
F
A
J
A1K2
K1
A1K2
A2
G1
K1
G2
K2
K1
A2
A1K2
.110 TAB
A1K2
(4 TYP.)
P - M8 THD
(2 TYP.)
L - DIA.
(4 TYP.)
Dimension
Inches
Millimeters
A
5.906
150
B
2.6970.02
68.50.2
C
1.575
40
D
1.535
39
E
1.260
32
F
1.181
30
G
0.906
23
H
0.787
20
J
0.630
16
K
0.276
7
L
0.2560.008 Dia. Dia. 6.50.2
M
M8 Metric
M8
*AIK2-AIK2 Connection made by external shorting bar.
Description:
Powerex Dual SCR
POW-R-BLOKTM Modules are
designed for use in applications
requiring phase control and
isolated packaging. The modules
are isolated for easy mounting
with other components on
common heatsinks.
POW-R-BLOKTM has been tested
and recognized by Underwriters
Laboratories (QQQX2 Power
Switching Semi-conductors).
Features:
Isolated Mounting
Glass Passivated Chips
Metal Baseplate
Low Thermal Impedance
UL Recognized
A
Applications:
Battery Supplies
Bridge Circuits
AC and DC Motor Control
Tap Changers
Lighting Control
Ordering Information:
Select the complete eight digit
module part number you desire
from the table below.
Example: CM530813 is an
800 Volt, 130 Ampere Dual SCR
POW-R-BLOKTM Module.
Voltage
Current Rating
Type
Volts (x100)
Amperes (x10)
CM53
08
13
S-33
Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
Dual SCR
POW-R-BLOKTM Modules
130 Amperes/800 Volts
CM530813
Outline Drawing
CM530813
Dual SCR POW-R-BLOKTM Modules
130 Amperes/800 Volts
A
S-34
Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
CM530813
Dual SCR POW-R-BLOKTM Modules
130 Amperes/800 Volts
Absolute Maximum Ratings
Characteristics
Symbol
CM530813
Units
Peak Forward Blocking Voltage
VDRM
800
Volts
Transient Peak Forward Blocking Voltage (Non-Repetitive), t < 5ms
VDSM
960
Volts
DC Forward Blocking Voltage
VD(DC)
640
Volts
Peak Reverse Blocking Voltage
VRRM
800
Volts
Transient Peak Reverse Blocking Voltage (Non-Repetitive), t < 5ms
VRSM
960
Volts
DC Reverse Blocking Voltage
VR(DC)
640
Volts
RMS On-State Current
IT(RMS)
205
Amperes
Average On-State Current, TC = 85C
IT(AV)
130
Amperes
Peak One-Cycle Surge (Non-Repetitive) On-State Current (60Hz)
ITSM
2600
Amperes
Peak One-Cycle Surge (Non-Repetitive) On-State Current (50Hz)
ITSM
2365
Amperes
I2t (for Fusing), 8.3 milliseconds
I2t
28000
A2sec
Critical Rate-of-Rise of On-State Current*
di/dt
100
Amperes/ s
Peak Gate Power Dissipation
PGM
10
Watts
Average Gate Power Dissipation
PG(AV)
3.0
Watts
Peak Forward Gate Voltage
VGFM
10
Volts
Peak Reverse Gate Voltage
VGRM
5.0
Volts
Peak Forward Gate Current
IGFM
4.0
Amperes
Storage Temperature
TSTG
-40 to 125
C
Operating Temperature
Tj
-40 to 125
C
Maximum Mounting Torque M6 Mounting Screw
--
26
in.-lb.
Maximum Mounting Torque M8 Terminal Screw
--
72
in.-lb.
Module Weight (Typical)
--
300
Grams
V Isolation
VRMS
2000
Volts
*Tj = 125C, IG = 1.0A, VD = 1/2 VDRM
Electrical and Thermal Characteristics,
Tj = 25C unless otherwise specified
Characteristics
Symbol
Test Conditions
CM530813
Units
Blocking State Maximums
Forward Leakage Current, Peak
IDRM
Tj = 125C, VDRM = Rated
30
mA
Reverse Leakage Current, Peak
IRRM
Tj = 125C, VRRM = Rated
30
mA
Conducting State Maximums
Peak On-State Voltage
VTM
ITM =390A
1.3
Volts
Switching Minimums
Critical Rate-of-Rise of Off-State Voltage
dv/dt
Tj = 125C, VD = 2/3 VDRM
500
Volts/ s
Thermal Maximums
Thermal Resistance, Junction-to-Case
R (J-C)
Per Module
0.22
C/Watt
Thermal Resistance, Case-to-Sink (Lubricated)
R (C-S)
Per Module
0.05
C/Watt
Gate Parameters Maximums
Gate Current-to-Trigger
IGT
VD = 6V, RL = 2
100
mA
Gate Voltage-to-Trigger
VGT
VD = 6V, RL = 2
3.0
Volts
Non-Triggering Gate Voltage
VGDM
Tj = 125C, VD = 1/2 VDRM
0.25
Volts
S-35
Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
CM530813
Dual SCR POW-R-BLOKTM Modules
130 Amperes/800 Volts
INSTANTANEOUS ON-STATE CURRENT, I
TM
,
(AMPERES)
MAXIMUM
ON-STATE CHARACTERISTICS
10
1
2.4
10
2
10
3
10
4
INSTANTANEOUS ON-STATE VOLTAGE, V
TM
, (VOLTS)
2.0
1.6
1.2
0.8
0.4
T
j
= 125
o
C
CYCLES AT 60 H
Z
MAXIMUM PEAK SURGE (NON-REPETITIVE)
CURRENT, I
TSM
, (AMPERES)
MAXIMUM ALLOWABLE PEAK SURGE
(NON-REPETITIVE) CURRENT
10
1
10
2
10
0
3200
2800
2400
2000
1600
1200
800
400
0
MAXIMUM ALLOWABLE CASE TEMPERATURE
(SINUSOIDAL WAVEFORM)
AVERAGE ON-STATE CURRENT, I
T(AV)
,
(AMPERES)
MAXIMUM ALLOWABLE CASE TEMPERATURE, T
C
, (
o
C)
0
130
360
o
RESISTIVE,
INDUCTIVE
LOAD PER
SINGLE
ELEMENT
120
110
100
90
80
70
60
50
20
40
60
80 100 120 140 160
= 30
o
120
o
60
o
90
o
180
o
MAXIMUM ON-STATE POWER DISSIPATION
(SINUSOIDAL WAVEFORM)
AVERAGE ON-STATE CURRENT, I
T(AV)
,
(AMPERES)
MAXIMUM POWER DISSIPATION, P
AV(MAX)
, (WATTS)
0
0
160
360
o
RESISTIVE, INDUCTIVE LOAD
PER SINGLE ELEMENT
20
40
60
80
100
120
140
20
40
60
80
100 120 140 160
180
o
= 30
o
120
o
60
o
90
o
50
MAXIMUM ALLOWABLE CASE TEMPERATURE
(RECTANGULAR WAVEFORM)
AVERAGE ON-STATE CURRENT, I
T(AV)
,
(AMPERES)
MAXIMUM ALLOWABLE CASE TEMPERATURE, T
C
, (
o
C)
0
60
70
80
90
100
110
120
130
360
o
RESISTIVE, INDUCTIVE
LOAD PER SINGLE
ELEMENT
120
o
270
o
= 30
o
90
o
60
o
DC
40
80
120
160
200
180
o
0
MAXIMUM AVERAGE ON-STATE POWER
DISSIPATION (RECTANGULAR WAVEFORM)
AVERAGE ON-STATE CURRENT, I
T(AV)
,
(AMPERES)
MAXIMUM POWER DISSIPATION, P
AV(MAX)
, (WATTS)
0
360
o
RESISTIVE, INDUCTIVE LOAD
PER SINGLE ELEMENT
40
80
120
160
200
40
80
120
160
200
120
o
180
o
270
o
= 30
o
60
o
90
o
DC
TIME, t, (SECONDS)
TRANSIENT THERMAL IMPEDANCE
CHARACTERISTICS (JUNCTION-TO-CASE)
0
10
-3
0.250
10
-2
10
-1
10
0
TRANSIENT THERMAL IMPEDANCE, Z
(J-C)
(t), (
o
C/WATT)
10
0
10
1
0.225
0.200
0.175
0.150
0.125
0.100
0.075
0.050
0.025
INSTANTANEOUS GATE CURRENT, I
G
, (mA)
TRIGGERING
CHARACTERISTICS
10
1
10
2
10
3
10
4
INSTANTANEOUS GATE VOLTAGE, V
G
, (VOLTS)
10
-1
10
0
10
1
10
2
V
GT
= 3.0V
P
G(AV)
=
3.0W
I
GFM
=
4.0A
I
GT
= 100mA
T
j
= 25
o
C
P
GM
= 10W
V
GDM
= 0.25V
V
GFM
= 10V
MAXIMUM ALLOWABLE CASE TEMPERATURE
(REVERSE PARALLEL CONNECTION)
MAXIMUM ALLOWABLE CASE TEMPERATURE, T
C
, (
o
C)
0
40
200
80 120 160
240 280 300
130
50
360
o
RESISTIVE,
INDUCTIVE LOAD
RMS ON-STATE CURRENT, I
(RMS)
, (AMPERES)
NOTE: THE CURVES INDICATE THE
RELATIONSHIP BETWEEN THE CASE
TEMPERATURE AND THE RMS
ON-STATE CURRENT FOR
EACH MODULE.
= 30
o
120
o
180
o
60
o
90
o
120
110
100
90
80
70
60
S-36
Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
CM530813
Dual SCR POW-R-BLOKTM Modules
130 Amperes/800 Volts
MAXIMUM ON-STATE POWER DISSIPATION
(REVERSE PARALLEL CONNECTION)
RMS ON-STATE CURRENT, I
(RMS)
, (AMPERES)
MAXIMUM POWER DISSIPATION, P
AV(MAX)
, (WATTS)
0
40
200
80 120 160
240 280 320
0
360
o
RESISTIVE,
INDUCTIVE LOAD
NOTE: THE CURVES INDICATE THE RELATIONSHIP BETWEEN
THE AVERAGE ON-STATE POWER DISSIPATION PER MODULE
AND THE RMS ON-STATE CURRENT.
50
100
150
200
250
300
350
400
= 180
o
60
o
30
o
120
o
90
o
MAXIMUM ALLOWABLE CASE TEMPERATURE
(SINGLE PHASE BRIDGE CONNECTION)
DC OUTPUT CURRENT, I
C
, (AMPERES)
MAXIMUM ALLOWABLE CASE TEMPERATURE, T
C
, (
o
C)
0
50
130
RESISTIVE,
INDUCTIVE
LOAD
360
o
NOTE: THE CURVES INDICATE THE RELATIONSHIP BETWEEN
THE CASE TEMPERATURE AND THE DC OUTPUT CURRENT
(FOR TWO ELEMENTS) WHEN USED IN THE SINGLE PHASE
BRIDGE CONFIGURATION.
40
80 120 160 200 240 280 320
= 30
o
60
o
90
o
180
o
120
o
120
110
100
90
80
70
60
MAXIMUM ON-STATE POWER DISSIPATION
(SINGLE PHASE BRIDGE CONNECTION)
DC OUTPUT CURRENT, I
O
, (AMPERES)
MAXIMUM POWER DISSIPATION, P
AV(MAX)
, (WATTS)
0
0
360
o
RESISTIVE,
INDUCTIVE LOAD
NOTE: THE CURVES INDICATE THE RELATIONSHIP BETWEEN
THE AVERAGE ON-STATE POWER DISSIPATION AND THE DC
OUTPUT CURRENT FOR THE SINGLE PHASE BRIDGE
CONFIGURATION (POWER DISSIPATION EXPRESSED FOR EACH
MODULE AND DC OUTPUT CURRENT EXPRESSED FOR THE PAIR)
40
80 120 160 200 240 280 320
= 30
o
120
o
90
o
60
o
40
80
120
160
200
240
280
320
360
400
180
o
MAXIMUM ALLOWABLE CASE TEMPERATURE
(THREE PHASE BRIDGE CONNECTION)
DC OUTPUT CURRENT, I
O
, (AMPERES)
MAXIMUM ALLOWABLE CASE TEMPERATURE, T
C
, (
o
C)
0
130
360
o
NOTE: THE CURVES INDICATE THE RELATIONSHIP BETWEEN
THE CASE TEMPERATURE AND THE DC OUTPUT CURRENT
(FOR THREE MODULES) IN THE THREE PHASE CONFIGURATION.
RESISTIVE,
INDUCTIVE LOAD
120
110
100
90
80
70
60
50
80
160
240
320
400
= 30
o
90
o
60
o
120
o
MAXIMUM ON-STATE POWER DISSIPATION
(THREE PHASE BRIDGE CONNECTION)
DC OUTPUT CURRENT, I
O
, (AMPERES)
MAXIMUM POWER DISSIPATION, P
AV(MAX)
, (WATTS)
0
0
NOTE: THE CURVES INDICATE THE RELATIONSHIP BETWEEN
THE ON-STATE POWER DISSIPATION (PER MODULE) AND THE
DC OUTPUT CURRENT (FOR THREE MODULES) IN THE THREE
PHASE BRIDGE CONFIGURATION.
360
o
RESISTIVE,
INDUCTIVE
LOAD PER
SINGLE ELEMENT
80
160
240
320
400
80
160
240
320
400
= 30
o
120
o
90
o
60
o
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