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ESM2030DV_03 Datasheet, PDF (2/8 Pages) STMicroelectronics – NPN DARLINGTON POWER MODULE
ESM2030DV
THERMAL DATA
Rthj-case
Rthj-case
Rthc-h
Thermal Resistance Junction-case (transistor)
Thermal Resistance Junction-case (diode)
Thermal Resistance Case-heatsink With Conductive
Grease Applied
Max
Max
Max
0.83
1.2
0.05
oC/W
oC/W
oC/W
ELECTRICAL CHARACTERISTICS (Tcase = 25 oC unless otherwise specified)
Symbol
Parameter
Test Conditions
ICER #
ICEV #
Collector Cut-off
Current (RBE = 5 Ω)
Collector Cut-off
Current (VBE = -5V)
VCE = VCEV
VCE = VCEV
VCE = VCEV
VCE = VCEV
Tj = 100 oC
Tj = 100 oC
IEBO # Emitter Cut-off Current
(IC = 0)
VCEO(SUS)* Collector-Emitter
Sustaining Voltage
hFE∗ DC Current Gain
VEB = 5 V
IC = 0.2 A L = 25 mH
Vclamp = 300 V
IC = 56 A VCE = 5 V
VCE(sat)∗ Collector-Emitter
Saturation Voltage
IC = 40 A
IC = 40 A
IC = 56 A
IC = 56 A
IB = 0.4 A
IB = 0.4 A
IB = 1.6 A
IB = 1.6 A
Tj = 100 oC
Tj = 100 oC
VBE(sat)∗ Base-Emitter
Saturation Voltage
IC = 56 A IB = 1.6 A
IC = 56 A IB = 1.6 A Tj = 100 oC
diC/dt
VCE(3
µs)••
Rate of Rise of
On-state Collector
Collector-Emitter
Dynamic Voltage
VCC = 300 V RC = 0 tp = 3 µs
IB1 = 0.6 A Tj = 100 oC
VCC = 300 V RC = 7.5 Ω
IB1 = 0.6 A
Tj = 100 oC
Min. Typ.
300
300
1.25
1.4
1.5
1.8
2.4
2.5
220 260
3
Max.
1.5
16
1
11
1
1.8
2.2
3
6
Unit
mA
mA
mA
mA
mA
V
V
V
V
V
V
V
A/µs
V
VCE(5 Collector-Emitter
µs)•• Dynamic Voltage
VCC = 300 V RC = 7.5 Ω
IB1 = 0.6 A
Tj = 100 oC
2.2
4
V
ts
Storage Time
tf
Fall Time
tc
Cross-over Time
IC = 40 A
VBB = -5 V
Vclamp = 300 V
L = 0.06 mH
VCC = 50 V
RBB = 0.6 Ω
IB1 = 0.4 A
Tj = 100 oC
VCEW
VF∗
Maximum Collector
Emitter Voltage
Without Snubber
Diode Forward Voltage
ICWoff = 67 A
IB1 = 1.6 A
VBB = -5 V
VCC = 50 V
L = 0.037 mH RBB = 0.6 Ω
Tj = 125 oC
IF = 56 A Tj = 100 oC
IRM Reverse Recovery
VCC = 200 V
IF = 56 A
Current
diF/dt = -220 A/µs L < 0.05 µH
Tj = 100 oC
∗ Pulsed: Pulse duration = 300 µs, duty cycle 1.5 %
# See test circuit in databook introduction
To evaluate the conduction losses of the diode use the following equations:
VF = 1.1 + 0.0045 IF P = 1.1 IF(AV) + 0.0045 I2F(RMS)
2
3
µs
0.35 0.6
µs
0.8
1.2
µs
300
V
1.15 1.6
V
12
17
A
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