STGW30V60DF
ActiveTRENCH GATE FIELD-STOP IGBT, V SERIES 600 V, 30 A VERY HIGH SPEED
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STGW30V60DF
ActiveTRENCH GATE FIELD-STOP IGBT, V SERIES 600 V, 30 A VERY HIGH SPEED
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Technical Specifications
Parameters and characteristics for this part
| Specification | STGW30V60DF |
|---|---|
| Current - Collector (Ic) (Max) [Max] | 60 A |
| Current - Collector Pulsed (Icm) | 120 A |
| Gate Charge | 163 nC |
| IGBT Type | Trench Field Stop |
| Mounting Type | Through Hole |
| Operating Temperature [Max] | 175 ░C |
| Operating Temperature [Min] | -55 °C |
| Package / Case | TO-247-3 |
| Power - Max [Max] | 258 W |
| Reverse Recovery Time (trr) | 53 ns |
| Supplier Device Package | TO-247-3 |
| Switching Energy | 383 µJ, 233 µJ |
| Td (on/off) @ 25°C | 45 ns, 189 ns |
| Test Condition | 15 V, 400 V, 30 A, 10 Ohm |
| Vce(on) (Max) @ Vge, Ic | 2.3 V |
| Voltage - Collector Emitter Breakdown (Max) [Max] | 600 V |
STGW30M65DF2 Series
Trench gate field-stop IGBT, V series 600 V, 30 A very high speed
| Part | Gate Charge | Power - Max [Max] | IGBT Type | Supplier Device Package | Operating Temperature [Min] | Operating Temperature [Max] | Current - Collector Pulsed (Icm) | Switching Energy | Mounting Type | Td (on/off) @ 25°C | Current - Collector (Ic) (Max) [Max] | Package / Case | Voltage - Collector Emitter Breakdown (Max) [Max] | Vce(on) (Max) @ Vge, Ic | Test Condition | Reverse Recovery Time (trr) | Td (on/off) @ 25°C | Td (on/off) @ 25°C | Td (on/off) @ 25°C | Switching Energy [custom] | Switching Energy [custom] | Voltage - Collector Emitter Breakdown (Max) | Vce(on) (Max) @ Vge, Ic [Max] |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
STMicroelectronics | 163 nC | 260 W | Trench Field Stop | TO-247 | -55 °C | 175 ░C | 120 A | 233 µJ 383 µJ | Through Hole | 45 ns 189 ns | 60 A | TO-247-3 | 600 V | 2.3 V | 10 Ohm 15 V 30 A 400 V | ||||||||
STMicroelectronics | 163 nC | 258 W | Trench Field Stop | TO-247-3 | -55 °C | 175 ░C | 120 A | 233 µJ 383 µJ | Through Hole | 45 ns 189 ns | 60 A | TO-247-3 | 600 V | 2.3 V | 10 Ohm 15 V 30 A 400 V | 53 ns | |||||||
STMicroelectronics | 102 nC | 200 W | TO-247-3 | -55 °C | 150 °C | 150 A | 181 µJ 305 µJ | Through Hole | 60 A | TO-247-3 | 600 V | 2.5 V | 10 Ohm 15 V 20 A 390 V | 118 ns | 29.5 ns | ||||||||
STMicroelectronics | 149 nC | 260 W | Trench Field Stop | TO-247-3 | -55 °C | 175 ░C | 120 A | 293 µJ | Through Hole | 60 A | TO-247-3 | 600 V | 2 V | 10 Ohm 15 V 30 A 400 V | -/146ns | ||||||||
STMicroelectronics | 105 nC | 220 W | TO-247-3 | -55 °C | 125 ¯C | 100 A | 2.4 mJ 4.3 mJ | Through Hole | 60 A | TO-247-3 | 1200 V | 3.85 V | 10 Ohm 15 V 20 A 960 V | 84 ns | |||||||||
STMicroelectronics | 102 nC | 200 W | TO-247-3 | -55 °C | 150 °C | 150 A | 181 µJ 305 µJ | Through Hole | 60 A | TO-247-3 | 600 V | 2.5 V | 10 Ohm 15 V 20 A 390 V | 40 ns | 118 ns | 29.5 ns | |||||||
STMicroelectronics | 149 nC | 260 W | Trench Field Stop | TO-247 | -55 °C | 175 ░C | 120 A | Through Hole | 60 A | TO-247-3 | 600 V | 2 V | 10 Ohm 15 V 30 A 400 V | 53 ns | 37 ns 146 ns | 383 µJ | 293 µJ | ||||||
STMicroelectronics | 80 nC | 258 W | Trench Field Stop | TO-247-3 | -55 °C | 175 ░C | 120 A | 300 µJ 960 µJ | Through Hole | 60 A | TO-247-3 | 2 V | 10 Ohm 15 V 30 A 400 V | 140 ns | 115 ns | 31.6 ns | 650 V | ||||||
STMicroelectronics | 110 nC | 220 W | TO-247-3 | -55 °C | 150 °C | 135 A | 1.66 mJ 4.44 mJ | Through Hole | 60 A | TO-247-3 | 10 Ohm 15 V 20 A 900 V | 152 ns | 275 ns | 29 ns | 900 V | 2.75 V |
Pricing
Prices provided here are for design reference only. For realtime values and availability, please visit the distributors directly
Description
General part information
STGW30M65DF2 Series
These devices are IGBTs developed using an advanced proprietary trench gate field-stop structure. The devices are part of the M series IGBTs, which represent an optimal balance between inverter system performance and efficiency where the low-loss and the short-circuit functionality are essential. Furthermore, the positive VCE(sat) temperature coefficient and the tight parameter distribution result in safer paralleling operation.
Documents
Technical documentation and resources