FP35R12KT4B11BPSA1

IGBT Module, PIM Three Phase Input Rectifier, 35 A, 1.85 V, 210 W, Module

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Manufacturer: INFINEON
Product type: IGBT Modules
SVHC: No SVHC (25-Jun-2025)
Product Range: EconoPIM 2 Series
IGBT Technology: IGBT 4 [Trench/Field Stop]
IGBT Termination: Press Fit
Power Dissipation: 210W
IGBT Configuration: PIM Three Phase Input Rectifier
Transistor Mounting: Panel
DC Collector Current: 35A
Power Dissipation Pd: 210W
Transistor Case Style: Module
Operating Temperature Max: -
Junction Temperature Tj Max: -
Continuous Collector Current: 35A
Collector Emitter Voltage Max: 1.2kV
Collector Emitter Voltage V(br)ceo: 1.2kV
Collector Emitter Saturation Voltage: 1.85V
Collector Emitter Saturation Voltage Vce(on): 1.85V

Delivery and price
Units per pack	50
Price	48.83 €
Current stock	10+
Lead time	30 days

Datasheet

## Technische�Information�/�Technical�Information 

> IGBT-ModuleIGBT-modules FP35R12KT4 

**==> picture [86 x 38] intentionally omitted <==**

EconoPIM™2�Modul�mit�Trench/Feldstopp�IGBT4�und�Emitter�Controlled4�Diode� EconoPIM™2�module�with�trench/fieldstop�IGBT4�and�Emitter�Controlled4�diode� 

## **Vorläufige�Daten Preliminary�Data** 

## **IGBT,Wechselrichter�/�IGBT,Inverter Höchstzulässige�Werte�/�Maximum�Rated�Values** 

|TechnischeInformation/TechnicalInformation<br>FP35R12KT4<br>IGBT-Module<br>IGBT-modules||
|---|---|
|EconoPIM™2ModulmitTrench/FeldstoppIGBT4undEmitterControlled4Diode<br>EconoPIM™2modulewithtrench/fieldstopIGBT4andEmitterControlled4diode<br>preparedby:AS<br>approvedby:RS<br>dateofpublication:2013-11-04<br>revision:2.0<br>**VorläufigeDaten**<br>**PreliminaryData**<br>**IGBT,Wechselrichter/IGBT,Inverter**<br>**HöchstzulässigeWerte/MaximumRatedValues**<br>Kollektor-Emitter-Sperrspannung<br>Collector-emittervoltage<br>Tvj= 25°C<br>VCES<br>1200<br>V<br>Kollektor-Dauergleichstrom<br>ContinuousDCcollectorcurrent<br>TC= 100°C, Tvj max= 175°C<br>IC nom<br>35<br>A<br>PeriodischerKollektor-Spitzenstrom<br>Repetitivepeakcollectorcurrent<br>tP= 1 ms<br>ICRM<br>70<br>A<br>Gesamt-Verlustleistung<br>Totalpowerdissipation<br>TC= 25°C, Tvj max= 175°C<br>Ptot<br>210<br>W<br>Gate-Emitter-Spitzenspannung<br>Gate-emitterpeakvoltage<br>VGES<br>+/-20<br>V<br>**CharakteristischeWerte/CharacteristicValues**<br>min.<br>typ.<br>max.<br>Kollektor-Emitter-Sättigungsspannung<br>Collector-emittersaturationvoltage<br>IC= 35 A, VGE= 15 V<br>IC= 35 A, VGE= 15 V<br>IC= 35 A, VGE= 15 V<br>VCE sat<br>1,85<br>2,15<br>2,25<br>2,25<br>V<br>V<br>V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Gate-Schwellenspannung<br>Gatethresholdvoltage<br>IC= 1,20 mA, VCE= VGE, Tvj= 25°C<br>VGEth<br>5,2<br>5,8<br>6,4<br>V<br>Gateladung<br>Gatecharge<br>VGE= -15 V ... +15 V<br>QG<br>0,27<br>µC<br>InternerGatewiderstand<br>Internalgateresistor<br>Tvj= 25°C<br>RGint<br>0,0<br>Ω<br>Eingangskapazität<br>Inputcapacitance<br>f = 1 MHz, Tvj= 25°C, VCE= 25 V, VGE= 0 V<br>Cies<br>2,00<br>nF<br>Rückwirkungskapazität<br>Reversetransfercapacitance<br>f = 1 MHz, Tvj= 25°C, VCE= 25 V, VGE= 0 V<br>Cres<br>0,07<br>nF<br>Kollektor-Emitter-Reststrom<br>Collector-emittercut-offcurrent<br>VCE= 1200 V, VGE= 0 V, Tvj= 25°C<br>ICES<br>1,0<br>mA<br>Gate-Emitter-Reststrom<br>Gate-emitterleakagecurrent<br>VCE= 0 V, VGE= 20 V, Tvj= 25°C<br>IGES<br>100<br>nA<br>Einschaltverzögerungszeit,induktiveLast<br>Turn-ondelaytime,inductiveload<br>IC= 35 A, VCE= 600 V<br>VGE= ±15 V<br>RGon= 27Ω<br>td on<br>0,16<br>0,17<br>0,17<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Anstiegszeit,induktiveLast<br>Risetime,inductiveload<br>IC= 35 A, VCE= 600 V<br>VGE= ±15 V<br>RGon= 27Ω<br>tr<br>0,03<br>0,04<br>0,04<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Abschaltverzögerungszeit,induktiveLast<br>Turn-offdelaytime,inductiveload<br>IC= 35 A, VCE= 600 V<br>VGE= ±15 V<br>RGoff= 27Ω<br>td off<br>0,33<br>0,43<br>0,45<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Fallzeit,induktiveLast<br>Falltime,inductiveload<br>IC= 35 A, VCE= 600 V<br>VGE= ±15 V<br>RGoff= 27Ω<br>tf<br>0,08<br>0,15<br>0,17<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>EinschaltverlustenergieproPuls<br>Turn-onenergylossperpulse<br>IC= 35 A, VCE= 600 V, LS= 20 nH<br>VGE= ±15 V, di/dt = 1100 A/µs (Tvj= 150°C)<br>RGon= 27Ω<br>Eon<br>3,90<br>5,10<br>5,60<br>mJ<br>mJ<br>mJ<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>AbschaltverlustenergieproPuls<br>Turn-offenergylossperpulse<br>IC= 35 A, VCE= 600 V, LS= 20 nH<br>VGE= ±15 V, du/dt = 3600 V/µs (Tvj= 150°C)<br>RGoff= 27Ω<br>Eoff<br>2,10<br>3,10<br>3,40<br>mJ<br>mJ<br>mJ<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Kurzschlußverhalten<br>SCdata<br>VGE ≤15 V, VCC= 900 V<br>VCEmax= VCES-LsCE·di/dt<br>ISC<br>130<br>A<br>Tvj= 150°C<br>tP ≤10 µs,<br>Wärmewiderstand,ChipbisGehäuse<br>Thermalresistance,junctiontocase<br>proIGBT/perIGBT<br>RthJC<br>0,72<br>K/W<br>Wärmewiderstand,GehäusebisKühlkörper<br>Thermalresistance,casetoheatsink<br>proIGBT/perIGBT<br>λPaste=1W/(m·K)/λgrease=1W/(m·K)<br>RthCH<br>0,335<br>K/W<br>TemperaturimSchaltbetrieb<br>Temperatureunderswitchingconditions<br>Tvj op<br>-40<br>150<br>°C||



1 

> IGBT-ModuleIGBT-modules FP35R12KT4 

## Technische�Information�/�Technical�Information 

**==> picture [86 x 38] intentionally omitted <==**

## **Vorläufige�Daten Preliminary�Data** 

## **Diode,�Wechselrichter�/�Diode,�Inverter Höchstzulässige�Werte�/�Maximum�Rated�Values** 

|PeriodischeSpitzensperrspannung<br>Repetitivepeakreversevoltage|Tvj= 25°C|VRRM|1200|V|
|---|---|---|---|---|
|Dauergleichstrom<br>ContinuousDCforwardcurrent||IF|35|A|
|PeriodischerSpitzenstrom<br>Repetitivepeakforwardcurrent|tP= 1 ms|IFRM|70|A|
|Grenzlastintegral<br>I²t-value|VR= 0 V, tP= 10 ms, Tvj= 125°C|I²t|240<br>|A²s|



## **Charakteristische�Werte�/�Characteristic�Values** 

||||||||
|---|---|---|---|---|---|---|
|**CharakteristischeWerte/CharacteristicValues**|||min.|typ.|max.||
|Durchlassspannung<br>Forwardvoltage|IF= 35 A, VGE= 0 V<br>IF= 35 A, VGE= 0 V<br>IF= 35 A, VGE= 0 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|VF||1,70<br>1,65<br>1,65|2,15|V<br>V<br>V|
|Rückstromspitze<br>Peakreverserecoverycurrent|IF= 35 A, - diF/dt = 1100 A/µs (Tvj=150°C)<br>VR= 600 V<br>VGE= -15 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|IRM||35,0<br>39,0<br>40,0||A<br>A<br>A|
|Sperrverzögerungsladung<br>Recoveredcharge|IF= 35 A, - diF/dt = 1100 A/µs (Tvj=150°C)<br>VR= 600 V<br>VGE= -15 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|Qr||3,40<br>6,30<br>7,20||µC<br>µC<br>µC|
|AbschaltenergieproPuls<br>Reverserecoveryenergy|IF= 35 A, - diF/dt = 1100 A/µs (Tvj=150°C)<br>VR= 600 V<br>VGE= -15 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|Erec||1,10<br>2,20<br>2,50||mJ<br>mJ<br>mJ|
|Wärmewiderstand,ChipbisGehäuse<br>Thermalresistance,junctiontocase|proDiode/perdiode|RthJC|||1,00|K/W|
|Wärmewiderstand,GehäusebisKühlkörper<br>Thermalresistance,casetoheatsink|proDiode/perdiode<br>λPaste=1W/(m·K)/λgrease=1W/(m·K)|RthCH||0,46||K/W|
|TemperaturimSchaltbetrieb<br>Temperatureunderswitchingconditions||Tvj op|-40||150|°C|



## **Diode,�Gleichrichter�/�Diode,�Rectifier Höchstzulässige�Werte�/�Maximum�Rated�Values** 

|PeriodischeSpitzensperrspannung<br>Repetitivepeakreversevoltage|Tvj= 25°C|VRRM|1600|1600||V|
|---|---|---|---|---|---|---|
|DurchlassstromGrenzeffektivwertproChip<br>MaximumRMSforwardcurrentperchip|TC= 80°C|IFRMSM|70|||A|
|GleichrichterAusgangGrenzeffektivstrom<br>MaximumRMScurrentatrectifieroutput|TC= 80°C|IRMSM|80|||A|
|StoßstromGrenzwert<br>Surgeforwardcurrent|tp= 10 ms, Tvj= 25°C<br>tp= 10 ms, Tvj= 150°C|IFSM|450<br>370|||A<br>A|
|Grenzlastintegral<br>I²t-value|tp= 10 ms, Tvj= 25°C<br>tp= 10 ms, Tvj= 150°C|I²t|1000<br>685|||A²s<br>A²s|
|**CharakteristischeWerte/CharacteristicValues**|||min.|typ.|max.||
|Durchlassspannung<br>Forwardvoltage|Tvj= 150°C, IF= 35 A|VF||0,95||V|
|Sperrstrom<br>Reversecurrent|Tvj= 150°C, VR= 1600 V|IR||1,00||mA|
|Wärmewiderstand,ChipbisGehäuse<br>Thermalresistance,junctiontocase|proDiode/perdiode|RthJC|||0,85|K/W|
|Wärmewiderstand,GehäusebisKühlkörper<br>Thermalresistance,casetoheatsink|proDiode/perdiode<br>λPaste=1W/(m·K)/λgrease=1W/(m·K)|RthCH||0,395||K/W|
|TemperaturimSchaltbetrieb<br>Temperatureunderswitchingconditions||Tvj op|-40||150|°C|
|preparedby:AS<br>approvedby:RS<br>dateofpublication:2013-11-04<br>revision:2.0|||||||
|preparedby:AS|dateofpublication:2013-11-04||||||
|approvedby:RS|revision:2.0||||||



2 

> IGBT-ModuleIGBT-modules FP35R12KT4 

## Technische�Information�/�Technical�Information 

**==> picture [86 x 38] intentionally omitted <==**

## **Vorläufige�Daten Preliminary�Data** 

## **IGBT,�Brems-Chopper�/�IGBT,�Brake-Chopper Höchstzulässige�Werte�/�Maximum�Rated�Values** 

|TechnischeInformation/TechnicalInformation<br>FP35R12KT4<br>IGBT-Module<br>IGBT-modules||
|---|---|
|preparedby:AS<br>approvedby:RS<br>dateofpublication:2013-11-04<br>revision:2.0<br>**VorläufigeDaten**<br>**PreliminaryData**<br>**IGBT,Brems-Chopper/IGBT,Brake-Chopper**<br>**HöchstzulässigeWerte/MaximumRatedValues**<br>Kollektor-Emitter-Sperrspannung<br>Collector-emittervoltage<br>Tvj= 25°C<br>VCES<br>1200<br>V<br>Kollektor-Dauergleichstrom<br>ContinuousDCcollectorcurrent<br>TC= 100°C, Tvj max= 175°C<br>IC nom<br>25<br>A<br>PeriodischerKollektor-Spitzenstrom<br>Repetitivepeakcollectorcurrent<br>tP= 1 ms<br>ICRM<br>50<br>A<br>Gesamt-Verlustleistung<br>Totalpowerdissipation<br>TC= 25°C, Tvj max= 175°C<br>Ptot<br>160<br>W<br>Gate-Emitter-Spitzenspannung<br>Gate-emitterpeakvoltage<br>VGES<br>+/-20<br>V<br>**CharakteristischeWerte/CharacteristicValues**<br>min.<br>typ.<br>max.<br>Kollektor-Emitter-Sättigungsspannung<br>Collector-emittersaturationvoltage<br>IC= 25 A, VGE= 15 V<br>IC= 25 A, VGE= 15 V<br>IC= 25 A, VGE= 15 V<br>VCE sat<br>1,85<br>2,15<br>2,25<br>2,25<br>V<br>V<br>V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Gate-Schwellenspannung<br>Gatethresholdvoltage<br>IC= 0,80 mA, VCE= VGE, Tvj= 25°C<br>VGEth<br>5,2<br>5,8<br>6,4<br>V<br>Gateladung<br>Gatecharge<br>VGE= -15 V ... +15 V<br>QG<br>0,20<br>µC<br>InternerGatewiderstand<br>Internalgateresistor<br>Tvj= 25°C<br>RGint<br>0,0<br>Ω<br>Eingangskapazität<br>Inputcapacitance<br>f = 1 MHz, Tvj= 25°C, VCE= 25 V, VGE= 0 V<br>Cies<br>1,45<br>nF<br>Rückwirkungskapazität<br>Reversetransfercapacitance<br>f = 1 MHz, Tvj= 25°C, VCE= 25 V, VGE= 0 V<br>Cres<br>0,05<br>nF<br>Kollektor-Emitter-Reststrom<br>Collector-emittercut-offcurrent<br>VCE= 1200 V, VGE= 0 V, Tvj= 25°C<br>ICES<br>1,0<br>mA<br>Gate-Emitter-Reststrom<br>Gate-emitterleakagecurrent<br>VCE= 0 V, VGE= 20 V, Tvj= 25°C<br>IGES<br>100<br>nA<br>Einschaltverzögerungszeit,induktiveLast<br>Turn-ondelaytime,inductiveload<br>IC= 25 A, VCE= 600 V<br>VGE= ±15 V<br>RGon= 37Ω<br>td on<br>0,05<br>0,06<br>0,06<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Anstiegszeit,induktiveLast<br>Risetime,inductiveload<br>IC= 25 A, VCE= 600 V<br>VGE= ±15 V<br>RGon= 37Ω<br>tr<br>0,03<br>0,04<br>0,05<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Abschaltverzögerungszeit,induktiveLast<br>Turn-offdelaytime,inductiveload<br>IC= 25 A, VCE= 600 V<br>VGE= ±15 V<br>RGoff= 37Ω<br>td off<br>0,34<br>0,43<br>0,45<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Fallzeit,induktiveLast<br>Falltime,inductiveload<br>IC= 25 A, VCE= 600 V<br>VGE= ±15 V<br>RGoff= 37Ω<br>tf<br>0,05<br>0,07<br>0,08<br>µs<br>µs<br>µs<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>EinschaltverlustenergieproPuls<br>Turn-onenergylossperpulse<br>IC= 25 A, VCE= 600 V, LS= t.b.d. nH<br>VGE= ±15 V<br>RGon= 37Ω<br>Eon<br>2,00<br>2,65<br>2,90<br>mJ<br>mJ<br>mJ<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>AbschaltverlustenergieproPuls<br>Turn-offenergylossperpulse<br>IC= 25 A, VCE= 600 V, LS= t.b.d. nH<br>VGE= ±15 V<br>RGoff= 37Ω<br>Eoff<br>1,40<br>2,20<br>2,40<br>mJ<br>mJ<br>mJ<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C<br>Kurzschlußverhalten<br>SCdata<br>VGE ≤15 V, VCC= 900 V<br>VCEmax= VCES-LsCE·di/dt<br>ISC<br>90<br>A<br>Tvj= 150°C<br>tP ≤10 µs,<br>Wärmewiderstand,ChipbisGehäuse<br>Thermalresistance,junctiontocase<br>proIGBT/perIGBT<br>RthJC<br>0,95<br>K/W<br>Wärmewiderstand,GehäusebisKühlkörper<br>Thermalresistance,casetoheatsink<br>proIGBT/perIGBT<br>λPaste=1W/(m·K)/λgrease=1W/(m·K)<br>RthCH<br>0,44<br>K/W<br>TemperaturimSchaltbetrieb<br>Temperatureunderswitchingconditions<br>Tvj op<br>-40<br>150<br>°C||



3 

> IGBT-ModuleIGBT-modules FP35R12KT4 

## Technische�Information�/�Technical�Information 

**==> picture [86 x 38] intentionally omitted <==**

**Vorläufige�Daten Preliminary�Data** 

## **Diode,�Brems-Chopper�/�Diode,�Brake-Chopper Höchstzulässige�Werte�/�Maximum�Rated�Values** 

|PeriodischeSpitzensperrspannung<br>Repetitivepeakreversevoltage|Tvj= 25°C|VRRM|1200|V|
|---|---|---|---|---|
|Dauergleichstrom<br>ContinuousDCforwardcurrent||IF|15|A|
|PeriodischerSpitzenstrom<br>Repetitivepeakforwardcurrent|tP= 1 ms|IFRM|30|A|
|Grenzlastintegral<br>I²t-value|VR= 0 V, tP= 10 ms, Tvj= 125°C|I²t|48,0<br>|A²s|



## **Charakteristische�Werte�/�Characteristic�Values** 

||||||||
|---|---|---|---|---|---|---|
|**CharakteristischeWerte/CharacteristicValues**|||min.|typ.|max.||
|Durchlassspannung<br>Forwardvoltage|IF= 15 A, VGE= 0 V<br>IF= 15 A, VGE= 0 V<br>IF= 15 A, VGE= 0 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|VF||1,75<br>1,75<br>1,75|2,25|V<br>V<br>V|
|Rückstromspitze<br>Peakreverserecoverycurrent|IF= 15 A, - diF/dt = 1000 A/µs (Tvj=150°C)<br>VR= 600 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|IRM||20,0<br>22,0<br>23,0||A<br>A<br>A|
|Sperrverzögerungsladung<br>Recoveredcharge|IF= 15 A, - diF/dt = 1000 A/µs (Tvj=150°C)<br>VR= 600 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|Qr||1,50<br>2,50<br>2,70||µC<br>µC<br>µC|
|AbschaltenergieproPuls<br>Reverserecoveryenergy|IF= 15 A, - diF/dt = 1000 A/µs (Tvj=150°C)<br>VR= 600 V<br>Tvj= 25°C<br>Tvj= 125°C<br>Tvj= 150°C|Erec||0,55<br>0,90<br>1,00||mJ<br>mJ<br>mJ|
|Wärmewiderstand,ChipbisGehäuse<br>Thermalresistance,junctiontocase|proDiode/perdiode|RthJC|||1,50|K/W|
|Wärmewiderstand,GehäusebisKühlkörper<br>Thermalresistance,casetoheatsink|proDiode/perdiode<br>λPaste=1W/(m·K)/λgrease=1W/(m·K)|RthCH||0,695||K/W|
|TemperaturimSchaltbetrieb<br>Temperatureunderswitchingconditions||Tvj op|-40||150|°C|



## **NTC-Widerstand�/�NTC-Thermistor** 

## **Charakteristische�Werte�/�Characteristic�Values** 

|**NTC-Widerstand/NTC-Thermistor**<br>|**NTC-Widerstand/NTC-Thermistor**<br>||||||
|---|---|---|---|---|---|---|
|**CharakteristischeWerte/CharacteristicValues**|||min.<br>typ.||max.||
|Nennwiderstand<br>Ratedresistance|TC= 25°C|R25||5,00||kΩ|
|AbweichungvonR100<br>DeviationofR100|TC= 100°C, R100= 493Ω|∆R/R|-5||5|%|
|Verlustleistung<br>Powerdissipation|TC= 25°C|P25|||20,0|mW|
|B-Wert<br>B-value|R2= R25exp [B25/50(1/T2- 1/(298,15 K))]|B25/50||3375||K|
|B-Wert<br>B-value|R2= R25exp [B25/80(1/T2- 1/(298,15 K))]|B25/80||3411||K|
|B-Wert<br>B-value|R2= R25exp [B25/100(1/T2- 1/(298,15 K))]|B25/100||3433||K|



Angaben�gemäß�gültiger�Application�Note. Specification�according�to�the�valid�application�note. 

prepared�by:�AS date�of�publication:�2013-11-04 approved�by:�RS revision:�2.0 

4 

IGBT-Module IGBT-modules 

## FP35R12KT4 

|Modul / Module|||||||
|---|---|---|---|---|---|---|
|Isolations-Prüfspannung<br>~~Isolation test voltage~~<br>Material Modulgrundplatte<br>Material of module baseplate|RMS, f = 50 Hz, t = 1 min.<br>~~ee ~~|VISOL<br> ~~ee~~||2,5<br>Cu||kV|
|Innere Isolation<br>Internal isolation|Basisisolierung (Schutzklasse 1, EN61140)<br>basic insulation (class 1, IEC 61140)|||Al2O3|||
|Kriechstrecke<br>Creepage distance|Kontakt - Kuhlk6rper / terminal to heatsink<br>Kontakt - Kontakt / terminal to terminal|||10,0||mm|
|Luftstrecke<br>Clearance|Kontakt - Kuhlkorper / terminal to heatsink<br>Kontakt - Kontakt / terminal to terminal|||7,5||mm|
|Vergleichszahl der Kriechwegbildung<br>Comperative tracking index||CTI||> 200|||
||||min.|typ.|max.||
|Warmewiderstand, Gehause bis Kuhlk6rper| <br>Thermal resistance, case to heatsink|Paste<br>grease<br> pro Modul / per module<br>= 1 W/(m-k)/<br>= 1 W/(m-k)|RthCH||0,02||K/W|
|Modulstreuinduktivität<br>Chip<br>~~Stray inductance module~~<br>Modulleitungswiderstand, Anschlusse -<br>Module lead resistance, terminals - chip|TC<br>~~ee ~~<br>= 25°C, pro Schalter / per switch|LsCE<br>RCC'+EE'<br>RAA'+CC'<br> ~~ee ee~~|35<br>4,00<br>3,00<br>~~ee~~|||nH<br>mΩ|
|Hoéchstzulassige Sperrschichttemperatur<br>Maximum junction temperature|Wechselrichter, Brems-Chopper/ inverter, brake-chopper<br>Gleichrichter/ rectifier|Tvj max|||175<br>150|°C<br>°C|
|Temperatur im Schaltbetrieb<br>Temperature under switching conditions|Wechselrichter, Brems-Chopper/ inverter, brake-chopper<br>Gleichrichter/ rectifier|Tvj op|-40<br>-40||150<br>150|°C<br>°C|
|Lagertemperatur<br>~~Storage temperature~~<br>Anzugsdrehmoment f. Modulmontage<br>Mounting torque for modul mounting|~~ee ~~<br>Schraube M5<br>- Montage gem. giltiger Applikationsschrift<br>Screw M5<br>- Mounting according to valid application note|Tstg<br>M<br> ~~ee ee~~|-40<br>125<br>3,00<br>-<br>6,00<br>~~ee~~|||°C<br>Nm|
|Gewicht<br>Weight||G||180||g|



5 

## IGBT-Module IGBT-modules 

## FP35R12KT4 

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I output C  characteristic CE) IGBT,Inverter (typical) I output C characteristic CE) IGBT,Inverter (typical)<br>VGE “255 V Tvj =150°C<br>70 70<br>65 Tvj = 25°C 65 VGE = 19V<br>— Tvj = 125°C OL L VGE = 17V L<br>60 Tvj = 150°C pf 60 VVGEGE = 15V = 13V A Le<br>55 PT fk eel ED 55 VGE = 11V ieleseeee<br>VGE =   9V<br>50 Pot TT iA a | | 50 pL AA Pe<br>45 45<br>pf tt a a ee 6a oe<br>40 PP ttPe ee 40 P P EP veo<br>35 Pot 35 eee<br>30 PoP tt A 30 poe<br>25 | | | yea ||TT | 25 P to AAAY<br>20 Pottee eet | ET 20 po||<br>15 15<br>10 Pt  oe 10 Po if<br>5 P| tFE fT | ct tt 5 ney<br>Peyt| | | tt| | || PF2Ane<br>0 0<br>0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5 4,0 4,5 5,0 0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5 4,0 4,5 5,0<br>VCE [V] VCE [V]<br> [A]  [A]<br>IC IC<br>**----- End of picture text -----**<br>


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I transfer C GE  characteristic ) IGBT,Inverter (typical) E switching on C losses off IGBT, C) Inverter (typical)<br>VCE oo VGE ~HeVR Gon S27 Ω ,R Goff =27 Ω ,V CE =600V<br>70 20<br>65 — Tvj = 25°C [ Eon, Tvj = 125°C pt<br>Tvj = 125°C 18 Eoff, Tvj = 125°C<br>60 fF Tvj = 150°C E-H Eon, Tvj = 150°C (i<br>Eoff, Tvj = 150°C<br>a 16 I a<br>5550 eee e eeee ee ea Pt a tt tT tT || TTc<br>14<br>a<br>45 Pot [te | | | | | | dT dT | | rT | FA<br>12<br>40 ee ee eee A<br>7 PT | | tT | TT Tr<br>35 10<br>FEES FERRER<br>30<br>8<br>25 Pf of | A 7<br>6<br>20 Pot EY Ptpitt t t T t T t eypat tt tte<br>A ER ee<br>15<br>4<br>Pie Aree P|a Tt | a eee |<br>10<br>2<br>a a ee<br>5<br>eT | | overt tT tT dt dT | | | |<br>0 P ett ||| 0 ee<br>5 6 7 8 9 10 11 12 0 10 20 30 40 50 60 70<br>VGE [V] IC [A]<br> [A]<br>IC E [mJ]<br>**----- End of picture text -----**<br>


6 

IGBT-Module IGBT-modules 

## FP35R12KT4 

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**----- Start of picture text -----**<br>
switching losses IGBT,Inverter (typical) transient thermal impedance IGBT, Inverter<br>Eon =f(R),E G off =f(R G) ZthJC = f(t)<br>VGE =+15V,1 C =35A,V CE =600V<br>12 1<br>=a EEonoff, T, Tvjvj = 125°C = 125°C P| tL feo TeH— ZthJC : IGBT SO E eee eee<br>Eon, Tvj = 150°C<br>10 f= Eoff, Tvj = 150°C booeeera Aa 2a) |<br>| | | ft EESLZ ZEnn aPLT VAI|ETT el<br>8<br>eS 26 ee eel7200<br>SaaecCORRE ane\~ IiHY<br>64 |ParePTT4 PfWz || dTTE tet| fettTET TLF 4|ddfo 0,1 Poi aa Aeeaaiel| el<br>2 att<br>i:    1    2    3    4<br>ri[K/W]:   0,0432   0,2376   0,2304   0,2088<br>SERSSRREREEE τ i[s]:    0,01    0,02    0,05    0,1    ||<br>PP CLE ‘oo l<br>0 0,01<br>0 20 40 60 80 100 120 140 160 180 200 220 240 0,001 0,01 0,1 1 10<br>RG [ Ω ] t [s]<br>Sicherer Ruckwarts-Arbeitsbereich IGBT,Wechselrichter Durchlasskennlinie der Diode, Wechselrichter (typisch)<br>(RBSOA) forward characteristic of Diode, Inverter (typical)<br>reverse bias safe operating area IGBT,Inverter (RBSOA) IF =f(V F)<br>IC CE)<br>VGE oe sy. R Goff =27 Ω ,T vj =150°C<br>80 70<br>IC, Modul 65 Tvj = 25°C<br>IC, Chip Tvj = 125°C<br>EIJI) BRA<br>70 — 60 Tvj = 150°C PE TE<br>55<br>PTE) ee e<br>60<br>50 Pt<br>50 Pte) 45 eee e te<br>40<br>ee eeePit ett tT lg td<br>40 35<br>30<br>PT) FEE<br>30<br>25<br>20 peepee<br>CEPI) SRR eee<br>20<br>15<br>ee eee<br>ee 10 Pt tT TT eA<br>10<br>5<br>PET) EP eee<br>0 0 | TT<br>0 200 400 600 800 1000 1200 1400 0,0 0,2 0,4 0,6 0,8 1,0 1,2 1,4 1,6 1,8 2,0 2,2 2,4<br>VCE  [V] VF [V]<br> [K/W]<br>E [mJ]<br>thJC<br>Z<br> [A]  [A]<br>IC IF<br>**----- End of picture text -----**<br>


7 

## IGBT-Module IGBT-modules Technische Information / FP35R12KT4 Technical Information 

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E switching rec F) losses Diode, Inverter (typical) E switching rec G) losses Diode, Inverter (typical)<br>RGon 1S Ω ,V CE =600V IF = 36 AV CE = 600 V<br>3,5 LS 3,5 LS<br>Erec, Tvj = 125°C Erec, Tvj = 125°C<br>Erec, Tvj = 150°C Erec, Tvj = 150°C<br>3,0 3,0<br>a ee ee<br>2,5 2,5<br>e e r H E<br>e LEER EEE<br>2,0 2,0<br>LYALL<br>1,5 1,5<br>EE) Lr Rte<br>TALULA ELE<br>1,0 1,0<br>ULL EEE E E E E E<br>0,5 0,5<br>0,0 0,0<br>0 10 20 30 40 50 60 70 0 20 40 60 80 100 120 140 160 180 200 220 240<br>IF [A] RG [ Ω ]<br>Transienter Warmewiderstand Diode, Wechselrichter Durchlasskennlinie der Diode, Gleichrichter (typisch)<br>Z ren thJC impedance Diode, Inverter ome IF F) characteristic of Diode, Rectifier (typical)<br>10 70<br>ZthJC : Diode 65 Tvj = 25°C<br>Tvj = 150°C<br>60<br>HES EA | Se e<br>55<br>PT TUT TENE ETE SeGGeeeeeneee<br>50<br>1<br>eee 45<br>Ee 40 Pi ttt EEE ye<br>FeJ oC 35 Pit ET TET er<br>30<br>a aI al<br>ATE 25<br>0,1 / ET<br>|T/T7A TtTT TTTTTT 2015 PT | | tt LL VAR Ey<br>7 yey i:    1    2    3    4    10 PT | | | ft tla ye i dd]<br>ri[K/W]:   0,06   0,33   0,32   0,29<br>I T τ i[s]:    0,01    T 0,02   0,05   0,1    5 TTP PPA<br>0,01 UE imo) ,  = E 0 C E<br>0,001 0,01 0,1 1 10 0,0 0,2 0,4 0,6 0,8 1,0 1,2 1,4<br>t [s] VF [V]<br>E [mJ] E [mJ]<br> [K/W]thJC  [A]IF<br>Z<br>**----- End of picture text -----**<br>


8 

IGBT-Module IGBT-modules 

## FP35R12KT4 

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IC =f(V CE) IF =f(V F)<br>VGE =15V<br>50 27<br>Tvj = 25°C Tvj = 25°C<br>45 Tvj = 125°C 24 Tvj = 125°C<br>F Tvj = 150°C e ee Tvj = 150°C<br>40<br>21<br>35<br>18<br>30<br>15<br>pfpi TTT TTT ATT<br>25<br>12<br>20<br>9<br>15<br>6<br>10<br>SCF tit t tat ty<br>5 3 [Lee]<br>PT [APT)]<br>PIA<br>0 0<br>TT TT Lee<br>0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5 4,0 0,0 0,2 0,4 0,6 0,8 1,0 1,2 1,4 1,6 1,8 2,0 2,2 2,4<br>VCE  [V] VF [V]<br> [A]  [A]<br>IC IF<br>**----- End of picture text -----**<br>


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100000<br>{— | Rtyp S a SeS A  eee<br>(a rs ce<br>e e ee eee<br>P EPEEEE EEE<br>10000<br>a ee<br>a<br>Ne ee ee ee ee ee ee ee ee<br>pot TNT tt<br>CAPR<br>NEE<br>1000<br>SSS<br>A<br>Pot eee eee<br>pjeeNe eee<br>Pt ftEP tftEE ftTE TTft t T tTTAHAE TT<br>SERRE RRRRRRRREE<br>100<br>0 20 40 60 80 100 120 140 160<br>TC [°C]<br>] Ω<br>R[<br>**----- End of picture text -----**<br>


9 

## Technische�Information�/�Technical�Information 

> IGBT-ModuleIGBT-modules FP35R12KT4 

## **Schaltplan�/�circuit_diagram_headline** 

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## **Vorläufige�Daten Preliminary�Data** 

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J<br>**----- End of picture text -----**<br>


## **Gehäuseabmessungen�/�package�outlines** 

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In fin e o n<br>**----- End of picture text -----**<br>


prepared�by:�AS date�of�publication:�2013-11-04 approved�by:�RS revision:�2.0 

10 

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IGBT-Module<br>IGBT-modules<br>**----- End of picture text -----**<br>


## FP35R12KT4 

## **Nutzungsbedingungen** 

## application. 

11

Updated at April 28, 2026

Infineon Technologies is a globally recognized leader in semiconductor solutions, renowned for driving innovation in power management, energy efficiency, and modern mobility. With a strong legacy of engineering excellence, the company provides highly reliable components designed to meet the rigorous demands of industrial, automotive, and advanced commercial applications. The core of our Infineon portfolio is centered on their industry-leading discrete semiconductors. We offer an extensive selection of single and dual MOSFETs, alongside a robust range of single IGBTs and advanced IGBT modules. These flagship power transistors are essential for high-efficiency power conversion and motor control, providing engineers with superior thermal performance and minimized switching losses. Beyond advanced field-effect transistors, the selection includes a comprehensive array of diodes and rectifiers, heavily featuring Schottky diodes, as well as fast-recovery and RF/PIN diodes. This power foundation is further supported by bipolar transistors, intelligent power modules, and thyristor SCR modules, delivering the critical building blocks required for complex power system designs. To support broader system integration, the portfolio also encompasses specialized solutions such as solid-state relays, AC/DC LED driver ICs, and Bluetooth communications modules. From high-power industrial rectifiers to wireless connectivity adapters, Infineon equips designers with the precision components needed to build efficient, scalable, and fully connected electronic systems.

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