10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 600V/ 75A General conditions BUCK = = = = VGEon VGEoff Rgon Rgoff + 15 V - 15 V 8Ω 8Ω Vout= 230 VAC Figure 1. Buck MOSFET BOOST = = = = VGEon VGEoff Rgon Rgoff + 15 V - 15 V 4Ω 4Ω Figure 2. Typical average static loss as a function of of output current IoRMS Ploss=f(Iout) Buck FWD Typical average static loss as a function of output current IoRMS Ploss=f(Iout) 70 Ploss (W) 50 Ploss (W) φ=0º φ=90º 60 40 50 30 40 30 20 20 φ=180º 10 10 φ=180º 0 0 0 20 Conditions: parameter: Tj= φ 40 125 from 60 I out (A) °C 0° in 12 to 0 20 Conditions: parameter: Tj= φ 80 180° 40 125 from steps 60 Buck MOSFET 0° 12 to 180° steps Figure 4. Typical average static loss as a function of phase displacement φ Ploss=f(φ) 80 °C in Figure 3. I out (A) Buck FWD Typical average static loss as a function of phase displacement φ Ploss=f(φ) 70 Ploss (W) 50 Ploss (W) IoutRMS=Imax IoutRMS=Imax 60 40 50 30 40 30 20 20 10 10 IoutRMS=6%Imin IoutRMS=6% Imax 0 0 0 Conditions: parameter: 50 Tj= IoRMS 100 125 from in steps of copyright by Vincotech 150 φ( º ) 200 °C 5A 10 to 75 A A 0 50 Conditions: parameter: Tj= IoRMS 100 125 from in steps of 1 150 φ( º ) 200 °C 5A 10 to 75 A A Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 Figure 5. Buck MOSFET 600V/ 75A Figure 6. Buck FWD Typical average switching loss as a function of phase displacement φ Ploss=f(φ) phase displacement φ Ploss=f(φ) 2,5 20 Ploss (W) Ploss (W) Typical average switching loss as a function of IoutRMS=Imax IoutRMS=Imax 2,0 15 1,5 10 1,0 5 0,5 IoutRMS=6% Imax IoutRMS=6% Imax 0 0,0 50 Conditions: parameter: 100 Tj= fsw= 125 20 °C kHz DC link= IoRMS 700 from V 150 0 50 Conditions: 5A in steps of 200 φ( º ) 10 to 75 A parameter: Tj= fsw= 125 20 °C kHz DC link= IoRMS 700 from V A Figure 7. 100 5A in steps of Buck MOSFET 150 10 to 75 A A Figure 8. Typical total loss as a function of phase displacement φ and output current IoRMS Ploss=f(IoRMS;φ) Buck FWD Typical total loss as a function of phase displacement φ and output current IoRMS Ploss=f(IoRMS;φ) 75 75 65 60-70 70 P loss (W) IoutRMS 70 P loss (W) 65 60-70 60 60 55 50-60 55 50-60 50 50 45 40-50 45 40-50 40 30-40 40 30-40 35 35 30 20-30 30 20-30 25 25 20 20 10-20 10-20 15 15 10 0 15 30 45 60 75 90 10 0-10 0-10 5 105 120 135 150 165 180 0 15 30 45 60 75 90 Tj= 125 °C DC link= fsw= 700 20 V kHz copyright by Vincotech 5 105 120 135 150 165 180 φ( º ) φ( º ) Conditions: 200 φ( º ) IoutRMS 0 Conditions: 2 Tj= 125 °C DC link= fsw= 700 20 V kHz Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 Figure 9. for Buck MOSFET+FWD 600V/ 75A Figure 10. for Buck MOSFET+FWD Typical available output current as a function of phase displacement φ Typical available output current as a function of switching frequency fsw Iout=f(φ) Iout=f(fsw) 70 Th=50°C Iout (A) Iout (A) 70 Th=50°C 60 60 50 50 40 40 Th=100°C 30 30 Th=100°C 20 20 10 10 0 0 0 30 60 90 120 150 180 1 10 fsw (kHz) φ Conditions: Tj= Tjmax-25 °C fsw= parameter: 700 V Heatsink temp. Th from 50 °C to in 10 °C 20 kHz Conditions: DC link= parameter: 100 steps Figure 11. °C φ= 0 ° Tj= Tjmax-25 °C DC link= Heatsink temp. Th from in 700 50 10 100 V °C to °C 100 steps °C for Buck IGBT+FWD Typical available 50Hz output current as a function of fsw and phase displacement φ Iout=f(fsw,φ) 180 165 φ I out (A) 150 135 60-65 120 55-60 105 50-55 90 75 45-50 60 40-45 45 30 35-40 15 2 4 8 16 32 64 0 128 fsw (kHz) Conditions: Tj= Tjmax-25 °C DC link= Th= copyright by Vincotech 700 80 V °C 3 Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet flowNPC 0 NPC Application Figure 12. Boost IGBT 600V/ 75A Figure 13. Typical average static loss as a function of output current Ploss=f(Iout) Boost FWD Typical average static loss as a function of output current Ploss=f(Iout) 70 φ=180º Ploss (W) Ploss (W) 100 φ=0º 60 80 50 60 40 30 40 20 20 10 φ=180º φ=0º 0 0 0 20 Conditions: parameter: 40 Tj= 125 φ from in 60 0 80 Iout (A) °C Conditions: 0° 12 to steps Figure 14. 180º parameter: Boost IGBT 20 40 Tj= 125 φ from in 80 Iout (A) °C 0° 12 to steps Figure 15. Typical average static loss as a function of phase displacement Ploss=f(φ) 180º Boost FWD Typical average static loss as a function of phase displacement Ploss=f(φ) FWD D1 100 IoutRMS=Imax Ploss (W) 70 Ploss (W) 60 IoutRMS=Imax 60 80 50 60 40 30 40 20 20 10 IoutRMS=6% Imax IoutRMS=6% Imax 0 0 0 Conditions: parameter: 50 Tj= IoRMS 100 125 from in steps of copyright by Vincotech 150 φ( º ) 0 200 °C 5 A to Conditions: parameter: 75 A 10 A 50 Tj= IoRMS 100 125 from in steps of 4 150 φ( º ) 200 °C 5 A to 75 A 10 A Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet flowNPC 0 NPC Application Figure 16. Boost IGBT 600V/ 75A Figure 17. Typical average switching loss as a function of phase displacement Ploss=f(φ) Boost FWD Typical average switching loss as a function of phase displacement Ploss=f(φ) 40 Ploss (W) 25 Ploss (W) IoutRMS=Imax IoutRMS=Imax 20 30 15 20 10 10 5 IoutRMS=6% Imax IoutRMS=6% Imax 0 0 0 50 Conditions: 150 fsw= Tj= 125 °C DC link= IoRMS 700 from V in steps of 5 A to 10 A A Figure 18. φ( º ) 0 200 20 kHz 50 Conditions: 75 A parameter: 100 Tj= 125 °C DC link= IoRMS 700 from V in steps of Boost IGBT 150 fsw= 20 kHz 5 A to 75 A 10 A A Figure 19. Typical total loss as a function of phase displacement and IoutRMS 200 φ( º ) Boost FWD Typical total loss as a function of phase displacement and IoutRMS Ploss=f(IoRMS;φ) Ploss=f(IoRMS;φ) 75 P loss (W) 65 60-70 75 70 IoutRMS 70 P loss (W) 60 65 IoutRMS parameter: 100 60 100-120 55 55 50-60 50 50 80-100 45 40-50 45 40 40 60-80 35 30-40 35 30 30 40-60 20-30 25 25 20 10-20 20 20-40 15 15 10 0-10 10 0 15 30 45 60 75 90 0-20 5 105 120 135 150 165 180 0 15 30 45 60 75 90 5 105 120 135 150 165 180 φ( º ) Conditions: Tj= 125 °C DC link= fsw= 700 20 V kHz copyright by Vincotech φ( º ) Conditions: 5 Tj= 125 °C DC link= fsw= 700 20 V kHz Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 Figure 20. Boost IGBT+FWD 600V/ 75A Figure 21. Typical available output current as a function of of phase displacement Iout=f(φ) Boost IGBT+FWD Typical available output current as a function of switching frequency Iout=f(fsw) 100 Iout (A) Iout (A) 100 Th=50°C 80 80 Th=50°C 60 60 Th=100°C 40 40 20 Th=100°C 20 0 0 0 30 Conditions: 60 90 120 150 Tj= Tjmax-25 °C DC link= 700 V parameter: Th from in fsw= Heatsink temp. 50 °C to 10 °C 180 φ( º ) 1 20 kHz Conditions: 10 Figure 22. °C f sw (kHz) Th from in Heatsink temp. 50 °C to 10 °C 1000 φ= 90° Tj= Tjmax-25 °C DC link= 700 V parameter: 100 steps 100 100 steps °C Boost IGBT+FWD Typical available 50Hz output current as a function of fsw and phase displacement Iout=f(fsw,φ) 180 I out (A) 165 φ 150 0-10 10-20 135 120 105 20-30 30-40 90 75 40-50 50-60 60 45 30 60-70 70-80 15 2 4 8 16 32 64 0 128 fsw (kHz) Conditions: Tj= Tjmax-25 °C DC link= Th= copyright by Vincotech 700 80 V °C 6 Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 Figure 23. per MODULE 600V/ 75A Figure 24. Typical available output current as a function of heat sink temperature Iout=f(Th) per MODULE Typical available output current as a function of phase displacement Iout=f(φ) 70 Iout (A) Iout (A) 70 2kHz 60 Th=50°C 60 50 50 40 40 128kHz 30 30 20 20 10 10 Th=100°C 0 0 60 70 Conditions: 80 90 T h ( o C) 0 100 Tj= Tjmax-25 °C DC link= φ= parameter: Conditions: 700 V 0° Switching freq. fsw from 2 in steps of factor 2 30 60 parameter: 128 Figure 25. kHz 150 50 10 °C to °C 180 100 steps Figure 26. Typical available output current as a function of switching frequency Iout=f(fsw) φ 700 V 20 kHz Heatsink temp. Th from in per MODULE 120 Tj= Tjmax-25 °C DC link= fsw= kHz to 90 per MODULE Typical available 50Hz output current as a function of fsw and phase displacement Iout=f(fsw,φ) 180 Iout (A) 70 φ Th=50°C 165 I out (A) 60 150 135 0-10 50 10-20 120 Th=100°C 105 40 20-30 30-40 90 75 30 40-50 50-60 60 20 45 30 60-70 10 15 0 2 1 10 Conditions: Tj= Tjmax-25 °C DC link= parameter: Th from in 50 10 copyright by Vincotech f sw (kHz) φ= 8 16 32 64 0 128 f sw (kHz) 0° Conditions: 700 V Heatsink temp. °C to °C 4 100 Tj= Tjmax-25 °C DC link= Th= 700 80 V °C 100 steps 7 Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 Figure 27. per MODULE Figure 28. Typical efficiency as a function of output power η=f(Pout) per MODULE Typical efficiency as a function of output power η=f(Pout) efficiency (%) 100,0 efficiency (%) 600V/ 75A 99,5 100,0 99,5 2kHz 99,0 99,0 98,5 φ=0º 98,5 98,0 97,5 98,0 128kHz φ=180º 97,0 97,5 96,5 97,0 96,0 0 5 10 15 20 0 Pout (kVA) Conditions: Tj= fsw= 125 20 °C kHz Conditions: DC link= parameter: 5 700 V phase displacement φ from 0° in steps of 30 ° Tj= DC link= parameter: to Figure 29. 125 700 15 Pout (kVA) 20 φ= 0 ° °C V Switching freq. fsw from 2 kHz to in steps of factor 2 180 ° per MODULE 10 128 kHz Figure 30. per MODULE Typical available output power as a function of Typical loss distribution as a function of heat sink temperature Pout=f(Th) output current Pout=f(Th) 180 Pout (kW) 15 Loss distribution 2kHz 160 12 T1 Stat. 140 D3-5 Sw. 120 9 D3-5 Stat. 128kHz 100 80 T3 Sw. 6 60 T3 Stat. 40 3 20 Conditions: parameter: Tj= Tjmax-25 °C DC link= 700 φ= 0 Switching freq. fsw from 2 kHz to in steps of factor 2 copyright by Vincotech 75 65 70 60 55 45 50 Iout (A) Conditions: V ° 128 40 T h ( C) 30 100 35 o 20 90 25 80 15 70 5 60 10 0 0 Tj= fsw= 125 20 °C kHz DC link= φ= 700 0° V kHz 8 Revision: 4 10-FZ06NRA075FU-P969F08 preliminary datasheet NPC Application flowNPC 0 Figure 31. Typical relativ loss distribution as a function of output current Pout=f(Th) per MODULE Figure 32. 600V/ 75A per MODULE 1,0 Loss distribution 0,9 0,8 T1 Stat. 0,7 D3-5 Sw. D3-5 Stat. 0,6 0,5 0,4 T3 Sw. 0,3 T3 Stat. 0,2 0,1 70 75 65 55 60 50 45 35 40 30 25 15 20 5 10 0,0 Iout (A) Conditions: Tj= fsw= DC link= φ= copyright by Vincotech 125 20 700 0° °C kHz V 9 Revision: 4