V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Maximum Ratings / Höchstzulässige Werte Parameter Condition Symbol Datasheet values Unit max. Transistor Inverter Transistor Wechselrichter Collector-emitter break down voltage Kollektor-Emitter-Sperrspannung DC collector current Kollektor-Dauergleichstrom Repetitive peak collector current Periodischer Kollektorspitzenstrom Power dissipation per IGBT Verlustleistung pro IGBT Gate-emitter peak voltage Gate-Emitter-Spitzenspannung SC withstand time* Kurzschlußverhalten* max. Chip temperature max. Chiptemperatur Tj=175°C Th=80°C, Tc=80°C VCE 600 V IC 55,8 73 225 A 89,4 135 ±20 W 6 360 175 us V °C 45 60,1 150 A tp limited by Tj max Icpuls Tj=175°C Ptot Th=80°C Tc=80°C VGE Tj150°C VCC=360V VGE=15V tSC Tjmax A V Diode Inverter Diode Wechselrichter DC forward current Dauergleichstrom Repetitive peak forward current Periodischer Spitzenstrom Power dissipation per Diode Verlustleistung pro Diode max. Chip temperature max. Chiptemperatur Tj=175°C Th=80°C, Tc=80°C IF tp limited by Tj max IFRM Tj=175°C Ptot Th=80°C Tc=80°C A Tjmax 58 88 175 W °C Tstg -40…+125 °C Top -40…+125 °C Vis 4000 Vdc min 12,7 mm min 12,7 mm Thermal properties Thermische Eigenschaften Storage temperature Lagertemperatur Operation temperature Betriebstemperatur Insulation properties Modulisolation Insulation voltage Isolationsspannung Creepage distance Kriechstrecke Clearance Luftstrecke Additional notes and remarks: Copyright by Vincotech t=1min * Allowed number of short circuits must be less than 1000 times, and time duration between short circuits should be more than 1 second! 1 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Characteristic values/ Charateristische Werte Description Symbol Conditions T(C°) Transistor Inverter Transistor Wechselrichter Gate emitter threshold voltage VGE(th) Gate-Schwellenspannung Collector-emitter saturation voltage Kollektor-Emitter Sättigungsspannung Collector-emitter cut-off Kollektor-Emitter Reststrom Gate-emitter leakage current Gate-Emitter Reststrom Integrated Gate resistor Integrirter Gate Widerstand Turn-on delay time Einschaltverzögerungszeit Rise time Anstiegszeit Turn-off delay time Abschaltverzögerungszeit Fall time Fallzeit Turn-on energy loss per pulse Einschaltverlustenergie pro Puls Turn-off energy loss per pulse Abschaltverlustenergie pro Puls Input capacitance Eingangskapazität Output capacitance Ausgangskapazität Reverse transfer capacitance Rückwirkungskapazität Gate charge Gate Ladung Thermal resistance chip to heatsink per chip Wärmewiderstand Chip-Kühlkörper pro Chip Thermal resistance chip to case per chip Wärmewiderstand Chip-Gehause pro Chip Coupled thermal resistance inverter diode-transistor Gekoppelte Wärmewiderstand Wechselrichter Diode-Transistor Coupled thermal resistance inverter transistor-transistor Gekoppelte Wärmewiderstand Wechselrichter Transistor-Transistor Tj=25°C Datasheet values Other conditions (Rgon-Rgoff) VR(V) VGE(V) VCE(V) VGS(V) VDS(V) VCE=VGE Unit IC(A) IF(A) Id(A) Min Typ Max 1200u 5 5,8 6,5 V 1,56 1,77 2,2 V Tj=125°C VCE(sat) Tj=25°C Tj=125°C ICES Tj=25°C Tj=125°C IGES Tj=25°C Tj=150°C Rgint td(on) tr td(off) tf Eon Eoff Cies Coss Crss QGate Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C 15 75 chip data 0 600 0,5 mA chip data 20 0 650 nA 4 Rg=1.2Ohm ±15 300 75 RthJC ns 158 Rg=1.2Ohm ±15 300 75 ns 25 Rg=1.2Ohm ±15 300 75 ns 231 Rg=1.2Ohm ±15 300 75 ns 79 ±15 300 75 mWs 1,07 ±15 300 75 mWs f=1MHz 0 25 2,35 4,7 f=1MHz 0 25 0,3 nF f=1MHz 0 25 0,145 nF tbd nC 1,06 K/W Thermal grease thickness50um Warmeleitpaste Dicke50um = 0,61 W/mK RthJH Ohm nF K/W RthJH K/W RthJH K/W Diode Inverter Diode Wechselrichter Diode forward voltage Durchlaßspannung Peak reverse recovery current Rückstromspitze Reverse recovery time Sperreverzögerungszeit Reverse recovered charge Sperrverzögerungsladung Reverse recovered energy Sperrverzögerungsenergie Thermal resistance chip to heatsink per chip Wärmewiderstand Chip-Kühlkörper pro Chip Thermal resistance chip to case per chip Wärmewiderstand Chip-Gehause pro Chip Coupled thermal resistance inverter transistor-diode Gekoppelte Wärmewiderstand Wechselrichter Transistor-Diode Coupled thermal resistance inverter diode-diode Gekoppelte Wärmewiderstand Wechselrichter Diode-Diode Copyright by Vincotech VF IRM trr Qrr Erec RthJH RthJC Tj=25°C Tj=150°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C Tj=25°C Tj=125°C 75 1,64 1,61 2,25 V A diF/dt = 2200 A/us -15 300 150 91,2 diF/dt = 2200 A/us -15 300 150 164 diF/dt = 2200 A/us -15 300 150 5,88 diF/dt = 2200 A/us Thermal grease thickness50um Warmeleitpaste Dicke50um = 0,61 W/mK -15 300 150 1,38 ns uC mWs 1,63 K/W K/W RthJH K/W RthJH K/W 2 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Output inverter Figure 1. Typical output characteristics Output inverter IGBT Figure 2. Typical output characteristics Output inverter IGBT Ic= f(VCE) Ic= f(VCE) 175 IC (A) IC (A) 175 140 140 105 105 70 70 35 35 0 0 0 1 2 3 4 VCE (V) 5 0 1 2 3 4 VCE (V) parameter: tp = 250 us Tj = 25 °C VGE parameter: from: 7 V to 17 V in 1 V steps parameter: tp = 250 us Tj = 125 °C VGE parameter: from: 7 V to 17 V in 1 V steps Figure 3. Figure 4. Typical transfer characteristics Output inverter IGBT Ic= f(VGE) 90 5 Typical diode forward current as a function of forward voltage IF=f(VF) Output inverter FRED IF (A) IC (A) 175 125 oC 25 oC 75 140 60 105 45 25 oC 125 oC 70 30 35 15 0 0 0 2 4 6 8 10 V GE (V) 12 parameter: tp = 250 us VCE = Copyright by Vincotech 0 10 V 0,5 1 1,5 2 2,5 VF (V) 3 parameter: tp = 250 us 3 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Output inverter Figure 5. Typical switching energy losses as a function of collector current Output inverter IGBT Figure 6. Typical switching energy losses as a function of gate resistor Output inverter IGBT E = f (RG) E = f (Ic) 5 E (mWs) E (mWs) 5 Eoff 4 4 3 3 Eon Eoff Eon 2 2 Erec 1 1 Erec 0 0 0 30 60 90 120 I C (A) 0 150 7 14 inductive load, Tj = 125 °C VCE = 300 V VGE= ±15 V Rgon= 4 Rgoff= 4 inductive load, Tj = 125 °C VCE = 300 V VGE= ±15 V Ic = 75 A Figure 7. Figure 8. Typical switching times as a function of collector current Output inverter IGBT 21 28 R G ( : ) 35 Typical switching times as a function of gate resistor Output inverter IGBT t = f (RG) t = f (Ic) 1 t ( Ps) t ( Ps) 1 tdoff tdon tdoff tdon 0,1 0,1 tf tf tr tr 0,01 0,01 0,001 0,001 0 30 60 90 120 IC (A) 150 0 inductive load, Tj = 125 °C VCE = 300 V VGE= ±15 V Rgon= 4 Rgoff= 4 Copyright by Vincotech 7 14 21 28 RG (: ) 35 inductive load, Tj = 125 °C VCE = 300 V VGE= ±15 V Ic = 75 A 4 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Output inverter Figure 9. Typical reverse recovery time as a function of IGBT turn on gate resistor Output inverter FRED diode Figure 10. Typical reverse recovery current as a function of IGBT turn on gate resistor Output inverter FRED diode trr = f (Rgon) IRRM = f (Rgon) 120 t rr( Ps) IrrM (A) 0,5 100 0,4 80 0,3 60 0,2 40 0,1 20 0 0 0 7 Tj = VR = IF= VGE= 14 125 300 75 ±15 21 28 R Gon ( : ) 35 0 °C V A V 14 Tj = VR = IF= VGE= Figure 11. Typical reverse recovery charge as a function of IGBT turn on gate resistor Output inverter FRED diode 125 300 75 ±15 21 28 R Gon ( : ) 35 °C V A V Figure 12. Typical rate of fall of forward and reverse recovery current as a function of IGBT turn on gate resistor Output inverter FRED diode dI0/dt,dIrec/dt= f (Rgon) Qrr = f (Rgon) 7 5000 direc / dt (A/ Ps) Qrr ( PC) 7 6 4000 5 3000 4 3 2000 dI0/dt dIrec/dt 2 1000 1 0 0 0 7 Tj = VR = IF= VGE= 14 125 300 75 ±15 21 28 R Gon ( :) 35 0 °C V A V Copyright by Vincotech 7 Tj = VR = IF= VGE= 5 14 125 300 75 ±15 21 28 R Gon ( :) 35 °C V A V Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Output inverter Figure 13. IGBT transient thermal impedance as a function of pulse width Figure 14. FRED transient thermal impedance as a function of pulse width ZthJH = f(tp) ZthJH = f(tp) 1 1 10 ZthJH (K/W) ZthJH (K/W) 10 100 0 10 D = 0,5 0,2 0,1 0,05 0,02 0,01 0,005 0.000 -1 10 D = 0,5 0,2 0,1 0,05 0,02 0,01 0,005 0.000 -1 10 -2 10 10-2 10-5 10-4 10-3 10-2 Parameter: D = tp / T 10-1 100 t p (s) 10-5 101 RthJH= 1,06 K/W 10-4 10-3 10-2 Parameter: D = tp / T IGBT thermal model values FRED thermal model values R (C/W) R (C/W) 0,02 0,13 0,47 0,31 0,09 0,05 Tau (s) 1,2E+01 1,4E+00 2,2E-01 7,1E-02 9,4E-03 4,4E-04 Copyright by Vincotech 0,03 0,17 0,74 0,49 0,13 0,09 6 10-1 100 t p (s) 101 RthJH= 1,63 K/W Tau (s) 1,3E+01 1,2E+00 1,6E-01 4,9E-02 7,6E-03 4,1E-04 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Output inverter Figure 15. Power dissipation as a function of heatsink temperature Output inverter IGBT Figure 16. Collector current as a function of heatsink temperature Output inverter IGBT Ptot = f (Th) Ic = f (Th) 100 IC (A) Ptot (W) 180 150 80 120 60 90 40 60 20 30 0 0 0 50 100 150 Th ( o C) 0 200 50 100 150 o Th ( C) 200 parameter: Tj= 175 ºC parameter: Tj= 175 ºC VGE= 15 V Figure 17. Power dissipation as a function of heatsink temperature Output inverter FRED Figure 18. Forward current as a function of heatsink temperature Output inverter FRED Ptot = f (Th) IF = f (Th) 125 IF (A) Ptot (W) 90 75 100 60 75 45 50 30 25 15 0 0 0 50 100 150 o Th ( C) 0 200 100 150 Th ( o C) 200 parameter: Tj= 175 ºC parameter: Tj= 175 ºC Copyright by Vincotech 50 7 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Thermistor Figure 1. Typical NTC characteristic as afunction of temperature RT = f (T) NTC-typical temperature characteristic R/ 25000 20000 15000 10000 5000 0 25 50 75 Copyright by Vincotech 100 T (°C) 125 8 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Switching definitions General conditions: Figure 1. Tj= 125 °C Rgon= Turn-off Switching Waveforms & definition of tdoff, tEoff (tEoff = integrating time for Eoff) Output inverter IGBT Figure 2. 4 Rgoff= 4 Turn-on Switching Waveforms & definition of tdon, tEon (tEon = integrating time for Eon) Output inverter IGBT 240 140 Ic tdoff 120 200 100 160 Uce 90% Uge 90% 80 120 % Ic % 60 80 tEoff 40 Uce Ic 1% Uge tdon 40 20 Uce Uge10% 0 Uce3% Ic10% 0 Uge tEon -20 -0,4 -40 -0,2 Uge(0%)= Uge(100%)= Uc(100%)= Ic(100%)= tdoff= tEoff= Figure 3. 0 0,2 time (us) -15 15 300 75 0,23 0,48 0,4 0,6 0,8 2,5 V V V A us us 2,6 Uge(0%)= Uge(100%)= Uc(100%)= Ic(100%)= tdon= tEon= Turn-off Switching Waveforms & definition of tf Output inverter IGBT Figure 4. 140 2,7 2,8 -15 15 300 75 0,16 0,35 2,9 time(us) 3 3,1 3,2 V V V A us us Turn-on Switching Waveforms & definition of tr Output inverter IGBT 260 120 Ic 220 fitted Uce Ic 100 180 Ic 90% 80 140 % Ic 60% % 60 100 40 Ic90% Uce Ic 40% tr 60 20 Ic10% 20 tf 0 Ic10% -20 -20 0,1 0,15 0,2 0,25 0,3 time (us) 0,35 0,4 2,7 0,45 Uc(100%)= 300 V Ic(100%)= 75 A tf= 0,079 us Copyright by Vincotech 2,75 2,8 2,85 time(us) 2,9 2,95 3 Uc(100%)= 300 V Ic(100%)= 75 A tr= 0,025 us 9 Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Switching definitions Figure 5. Turn-off Switching Waveforms & definition of tEoff Output inverter IGBT Figure 6. 120 Turn-on Switching Waveforms & definition of tEon Output inverter IGBT 120 Poff Eoff 100 100 80 80 Pon Eon 60 60 % 40 % 40 20 20 Uge10% Uce3% 0 0 tEon Uge90% tEoff Ic 1% -20 -20 -0,2 -0,05 0,1 0,25 time (us) 0,4 0,55 2,5 0,7 2,6 2,7 Poff(100%)= 22,48 kW Eoff(100%)= 2,36 mJ tEoff= 0,48 us Pon(100%)= Eon(100%)= tEon= Figure 7. Gate voltage vs Gate charge Figure 8. Output inverter IGBT 20 120 15 80 2,8 2,9 time(us) 3 3,1 3,2 22,5 kW 1,07 mJ 0,35 us Turn-off Switching Waveforms & definition of trr Output inverter FRED Id trr 10 40 Ud Uge (V) 5 0 % 0 IRRM10% -40 -5 -80 fitted -10 IRRM90% -120 -15 -20 -200 IRRM100% -160 0 Ugeoff= Ugeon= Uc(100%)= Ic(100%)= Qg= 200 -15 15 300 75 811 400 Qg (nC) 600 800 2,7 1000 2,9 3 3,1 3,2 time(us) V V V A nC Copyright by Vincotech 2,8 Ud(100%)= Id(100%)= IRRM(100%)= trr= 10 300 75 91 0,16 V A A us Revision: 1 V23990-P706-F-PM final data sheet flow 90PACK 1 600V/ 75A V23990-P706-F-01-14 Switching definitions Figure 9. Turn-on Switching Waveforms & definition of tQrr (tQrr= integrating time for Qrr) Output inverter FRED Figure 10. Turn-on Switching Waveforms & definition of tErec (tErec= integrating time for Erec) Output inverter FRED 120 150 Qrr 100 100 Erec Id 80 50 tQint tErec 60 % % 0 40 -50 20 Prec -100 0 -20 -150 2,5 2,7 2,9 time(us) 3,1 3,3 2,5 3,5 Id(100%)= 75 A Qrr(100%)= 5,881 uC tQint= 0,33 us Copyright by Vincotech 2,7 Prec(100%)= Erec(100%)= tErec= 11 2,9 time(us) 3,1 3,3 3,5 22,5 kW 1,38 mJ 0,33 us Revision: 1