10-FY06BIA050SG-M523E18 preliminary datasheet DC Boost Application flowSOL 1 BI 600V/50A General conditions BOOST = = = = VGEon VGEoff Rgon Rgoff Figure 1. IGBT 15 V -15 V 4Ω 4Ω Figure 2. Typical average static loss as a function of input current IiRMS Ploss=f(Iin) FWD Typical average static loss as a function of input current IiRMS Ploss=f(Iin) 70 Vin/Vout=1 Ploss (W) Ploss (W) 100 Vin/Vout=0,2 60 80 50 60 40 30 40 20 20 10 Vin/Vout=1 Vin/Vout=0,2 0 0 10 20 30 40 0 50 0 Iin (A) 125 °C Conditions: Tj= Ratio of input DC voltage to output DC voltage parameter: Vin/Vout from in 10 20 30 40 Iin (A) 50 Conditions: Tj= 125 °C Ratio of input DC voltage to output DC voltage 0,2 0,2 to steps 1,0 Figure 3. parameter: Vin/Vout from in 0,2 0,2 to steps 1,0 Figure 4. IGBT Typical average switching loss as a function of input current Ploss=f(Iin) FWD Typical average switching loss as a function of input current Ploss=f(Iin) 8 100 Ploss (W) Ploss (W) fsw="to" kHz fsw="to" kHz 80 6 60 4 40 2 20 fsw="from" kHz fsw="from" kHz 0 0 0 10 20 30 40 0 50 10 20 30 40 Iin (A) Conditions: Sw. freq. Tj= 125 350 Vout = fsw from 8 in steps of factor 2 copyright by Vincotech °C V Conditions: kHz to 64 50 Iin (A) kHz Sw. freq. 1 Tj= 125 Vout = 350 fsw from 8 in steps of factor 2 °C V kHz to 64 kHz Revision: 1 10-FY06BIA050SG-M523E18 preliminary datasheet DC Boost Application flowSOL 1 BI Figure 5. per PHASE Figure 6. Typical available input current as a function of Vin/Vout Iin=f(Vin/Vout) per PHASE Typical available input current as a function of switching frequency Iin=f(fsw) 45 Th=60°C 30 Iin (A) Iin (A) 600V/50A 40 25 35 30 20 Th=60°C 25 15 20 15 Th=100°C 10 10 5 Th=100°C 5 0 0,0 0,2 0,4 0,6 0,8 0 1,0 1 10 100 1000 Vin/Vout Conditions: DC link= parameter: 350 Tj= Tjmax-25°C V Heatsink temp. Th from in fsw= 16 fsw (kHz) Conditions: DC link= kHz parameter: 60 10 °C to °C 100 steps Figure 7. °C per PHASE 350 Tj= Tjmax-25°C V Heatsink temp. Th from in Vin 60 10 °C to °C 250 V 100 steps °C Figure 8. per PHASE Typical available input current as a function of Typical available electric input power as a function fsw and Vin/Vout Iin=f(fsw,Vin/Vout) of heatsink temperature Pin=f(Th) 0,10 Pin (kW) Vin/Vout 0,20 Iin (A) 8 0,30 7 6 "from" kHz 0,40 35,0-40,0 5 30,0-35,0 0,50 25,0-30,0 to" kHz 4 20,0-25,0 0,60 15,0-20,0 3 10,0-15,0 0,70 5,0-10,0 2 0,0-5,0 0,80 1 4 8 16 32 64 0,90 128 0 60 70 80 90 fsw (kHz) Conditions: Tj= Tjmax-25°C DC link= Th= copyright by Vincotech 100 Th (oC) Conditions: 350 V 80 °C Vin Sw. freq. 2 Tj= Tjmax-25°C 250 V fsw from 8 DC link= kHz to 350 V 64 kHz Revision: 1 10-FY06BIA050SG-M523E18 preliminary datasheet DC Boost Application flowSOL 1 BI Figure 9. 600V/50A per PHASE Typical efficiency as a function of input power η=f(Pin) efficiency (%) 100,0 99,5 "from" kHz 99,0 98,5 "to" kHz 98,0 97,5 97,0 0 2 4 6 8 10 Pin (kW) Conditions: Tj= Tjmax-25°C Vin parameter: 250 V Sw. freq. fsw from copyright by Vincotech DC link= 8 kHz to 350 V 64 kHz 3 Revision: 1 10-FY06BIA050SG-M523E18 preliminary datasheet H-Bridge Application flowSOL 1 BI 600V/50A General conditions H Bridge SPWM VGEon = 15 V VGEoff = 0 V Rgon = 4 Ω Rgoff = 4 Ω IGBT Figure 1 Typical average static loss as a function of output current Ploss = f(Iout) 45 60 Ploss (W) Ploss (W) FWD Figure 2 Typical average static loss as a function of output current Ploss = f(Iout) Voutpk/Vin* cosfi=1 40 50 35 Voutpk/Vin* cosfi=-1 40 30 25 30 20 20 15 10 10 Voutpk/Vin* cosfi=-1 5 Voutpk/Vin* cosfi=1 0 0 0 At Tj = 5 10 15 20 25 30 35 40 0 45 50 Iout (A) At Tj = °C 125 Mi*cosfi from -1 to 1 in steps of 0,2 5 10 125 15 20 25 30 35 45 50 Iout (A) °C Mi*cosfi from -1 to 1 in steps of 0,2 IGBT Figure 3 Typical average switching loss as a function of output current Typical average switching loss as a function of output current Ploss = f(Iout) Ploss (W) Ploss (W) fsw="to"kHz 16 FWD Figure 4 20 Ploss = f(Iout) 2,5 2,0 12 1,5 8 1,0 4 0,5 fsw="to" kHz fsw="from" kHz fsw="from" kHz 0 0,0 0 At Tj = 40 5 10 125 15 20 25 30 35 40 45 Iout (A) 50 0 10 15 20 25 30 35 Iout (A) At Tj = °C DC link = 350 V fsw from 4 kHz to 32 kHz in steps of factor 2 copyright by Vincotech 5 125 °C DC link = 350 V fsw from 4 kHz to 32 kHz in steps of factor 2 4 Revision: 1 10-FY06BIA050SG-M523E18 preliminary datasheet Output Inverter Application flowSOL 1 BI Phase Figure 5 Typical available 50Hz output current as a function Mi*cosfi Phase Figure 6 Typical available 50Hz output current as a function of switching frequency Iout = f(Mi*cosfi) Th=60°C 70 Iout = f(fsw) 80 Iout (A) 80 Iout (A) 600V/50A Th=60°C 70 60 60 50 50 40 Th=100°C 40 Th=100°C 30 30 20 20 10 10 0 -1,0 -0,6 -0,2 0,2 0,6 0 1,0 1 10 100 Voutpk/Vin*cosfi At Tj = 125 fsw (kHz) At Tj = °C DC link = 350 V fsw = 16 kHz Th from 60 °C to 100 °C in steps of 5 °C 125 °C DC link = 350 V Mi*cosfi = 1 Th from 60 °C to 100 °C in steps of 5 °C Phase Figure 7 -0,80 60,0-65,0 -0,60 60 Th=60°C Iout (A) Iout (A) Typical available output current as a function of switching frequency Iout=f(fsw) Voutpk/Vin*cosfi -1,00 Phase Figure 8 Typical available 50Hz output current as a function of Voutpk/Vin*cosfi and switching frequency Iout=f(fsw,Mi*cosfi) 50 55,0-60,0 -0,40 50,0-55,0 40 45,0-50,0 -0,20 40,0-45,0 35,0-40,0 30 0,00 30,0-35,0 Th=100°C 25,0-30,0 20,0-25,0 0,20 15,0-20,0 20 10,0-15,0 0,40 5,0-10,0 0,0-5,0 0,60 10 0,80 0 1,00 2 4 8 16 32 64 1 10 fsw (kHz) 100 fsw (kHz) At Tj = 125 °C At Tj = 125 °C DC link = Th = 350 80 V °C DC link = Mi*cosfi = 350 0 V Th from 60 °C to 100 °C in steps of 5 °C copyright by Vincotech 5 Revision: 1 10-FY06BIA050SG-M523E18 preliminary datasheet Output Inverter Application flowSOL 1 BI Inverter Figure 9 Inverter Figure 10 Typical available peak output power as a function of Pout=f(Th) heatsink temperature Typical efficiency as a function of output power efficiency=f(Pout) 100,0 efficiency (%) 18 Pout (kW) 600V/50A 16 14 99,5 99,0 12 "from" kHz "from" kHz 98,5 10 98,0 8 "to" kHz 97,5 "to" kHz 6 97,0 4 96,5 2 96,0 0 60 70 80 90 0 100 2 4 6 Th (oC) At Tj = 125 10 12 Pout (kW) At Tj = °C DC link = 350 V Mi = 1 cosfi = 1 fsw from 4 kHz to 32 kHz in steps of factor 2 copyright by Vincotech 8 125 °C DC link = 350 V Mi = 1 cosfi = 1 fsw from 4 kHz to 32 kHz in steps of factor 2 6 Revision: 1 10-FY06BIA050SG-M523E18 preliminary datasheet PRODUCT STATUS DEFINITIONS Datasheet Status Target Preliminary Final Product Status Definition Formative or In Design This datasheet contains the design specifications for product development. Specifications may change in any manner without notice. The data contained is exclusively intended for technically trained staff. First Production This datasheet contains preliminary data, and supplementary data may be published at a later date. Vincotech reserves the right to make changes at any time without notice in order to improve design. The data contained is exclusively intended for technically trained staff. Full Production This datasheet contains final specifications. Vincotech reserves the right to make changes at any time without notice in order to improve design. The data contained is exclusively intended for technically trained staff. DISCLAIMER The information given in this datasheet describes the type of component and does not represent assured characteristics. For tested values please contact Vincotech.Vincotech reserves the right to make changes without further notice to any products herein to improve reliability, function or design. Vincotech does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights, nor the rights of others. LIFE SUPPORT POLICY Vincotech products are not authorised for use as critical components in life support devices or systems without the express written approval of Vincotech. As used herein: 1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, or (c) whose failure to perform when properly used in accordance with instructions for use provided in labelling can be reasonably expected to result in significant injury to the user. 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. copyright by Vincotech 7 Revision: 1