10-FZ06BIA041FS01-P898E10 preliminary datasheet flowsol 0 bi 600v / 41mohm v geon = v geof f = r g on = r goff = figure 1. mosfet figure 2. fwd typical average static loss as a function of typical average static loss as a function of input current ii rms input current ii rms p loss =f(i in )p loss =f(i in ) conditions: t j = 125 c conditions: t j = 125 c ratio of input dc voltage to output dc voltage ratio of input dc voltage to output dc voltage parameter: v in /v out from 0,2 to 1,0 parameter: v in /v out from 0,2 to 1,0 in 0,2 steps in 0,2 steps figure 3. mosfet figure 4. fwd typical average switching loss as a function of typical average switching loss as a function of input current input current p loss =f(i in )p loss =f(i in ) conditions: tj= 125 c conditions: tj= 125 c v out = 350 v v out = 350 v sw. freq. fsw from 16 khz to 128 khz sw. freq. fsw from 16 khz to 128 khz in steps of factor 2 in steps of factor 2 8 ? dc boost application general conditions boost 10 v 0 v 8 ? 0 20 40 60 80 100 120 0 1020304050 iin (a) ploss (w) v in /v out =0,2 v in /v out =1 v in /v out =1 0 20 40 60 80 100 120 0 1020304050 iin (a) ploss (w) v in /v out =0,2 f sw ="to" khz 0 10 20 30 40 50 60 0 1020304050 iin (a) ploss (w) f sw ="from" khz f sw ="from" khz f sw ="to" khz 0 1 2 3 4 5 6 7 0 1020304050 iin (a) ploss (w) 1 revis ion: 1 copyright by vincotech
10-FZ06BIA041FS01-P898E10 preliminary datasheet flowsol 0 bi 600v / 41mohm dc boost application figure 5. per phase figure 6. per phase typical available input current as a function of typical available input current as a function of v in /v out switching frequency i in =f(v in /v out )i in =f(f sw ) conditions: t j =t j ma x -25 c conditions: t j =t j ma x -25 c dc link= 350 v f sw = 20 khz dc link= 350 v vin 250 v parameter: heatsink temp. parameter: heatsink temp. th from 60 c to 100 c th from 60 c to 100 c in 10 c steps in 10 c steps figure 7. per phase figure 8. per phase typical available input current as a function of typical available electric input power as a function f sw and v in /v out of heatsink temperature i in =f(f sw ,v in /v out ) p in =f(t h ) conditions: tj= t j ma x -25 c conditions: tj= t j ma x -25 c dc link= 350 v vin 250 v dc link= 350 v th= 80 c sw. freq. fsw from 16 khz to 128 khz th=60c th=100c 0 5 10 15 20 25 30 35 40 45 0,1 0,2 0,3 0,4 0,5 0,6 0,7 0,8 0,9 1,0 vin/vout iin (a) th=60c th=100c 0 5 10 15 20 25 30 35 1 10 100 1000 f sw (khz) iin (a) 8 16 32 64 128 256 0,10 0,20 0,30 0,40 0,50 0,60 0,70 0,80 0,90 iin (a) 34,0-36,0 32,0-34,0 30,0-32,0 28,0-30,0 26,0-28,0 24,0-26,0 22,0-24,0 20,0-22,0 18,0-20,0 16,0-18,0 14,0-16,0 vin/vout fsw (khz) "from" khz 0 1 2 3 4 5 6 7 8 9 60 65 70 75 80 85 90 95 100 th ( o c) pin (kw) to" khz 2 revis ion: 1 copyright by vincotech
10-FZ06BIA041FS01-P898E10 preliminary datasheet flowsol 0 bi 600v / 41mohm dc boost application figure 9. per phase typical efficiency as a function of input power =f(pin) conditions: tj= t j ma x -25 c vin 250 v dc link= 350 v parameter: sw. freq. fsw from 16 khz to 128 khz "from" khz "to" khz 98,00 98,25 98,50 98,75 99,00 99,25 99,50 99,75 100,00 024681012 p in (kw) efficiency (%) 3 revis ion: 1 copyright by vincotech
10-FZ06BIA041FS01-P898E10 preliminary datasheet flowsol 0 bi 600v / 41mohm v geon = v geof f = r g on = r g off = figure 1. mosfet figure 2. fwd typical avarage static loss typical avarage static loss as a function of output current as a function of output current ploss=f(iout) ploss=f(iout) conditions: t j ma x = 125 c conditions: t j ma x = 150 c ratio of output peak to input dc voltage ratio of output peak to input dc voltage parameter v out pk /v in from 0,2 to 1,0 parameter v out pk /v in from 0,2 to 1,0 in 0,2 steps in 0,2 steps figure 3. mosfet figure 4. fwd typical avarage switching loss typical avarage switching loss as a function of output current as a function of output current ploss=f(iout) ploss=f(iout) conditions: tjmax= 125 c conditions: tjmax= 150 c dc link= 400 v dc link= 400 v switching freq. fsw from 4 khz to 32 khz switching freq. fsw from 4 khz to 32 khz parameter in * 2 steps parameter in * 2 steps 0 v 8 ? 8 ? cosfi = 1 h bridge application general conditions buck halfwave conduction 10 v voutpk/vin=0,2 voutpk/vin=1 0 10 20 30 40 50 60 70 80 90 100 0 102030405060 iout (a) ploss (w) voutpk/vin=0,2 voutpk/vin=1 0 5 10 15 20 25 30 35 40 45 50 0 102030405060 iout (a) ploss (w) fsw="from" khz fsw="to"khz 0 2 4 6 8 10 12 14 16 18 0 102030405060 iout (a) ploss (w) fsw="from" khz fsw="to" khz 0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5 0 102030405060 iout (a) ploss (w) 4 revis ion: 1 copyright by vincotech
10-FZ06BIA041FS01-P898E10 preliminary datasheet figure 5. per phase figure 6. per phase typical available output current typical available output current as a function of voutpk/vin as a function of switching frequency fullwave iout=f(voutpk/vin) fullwave iout=f(fsw) conditions: tj=tjmax conditions: tj=tjmax fsw= 16 khz dc link= 400 v vout 230 v dc link= 400 v heatsink temp. th from 60 c to 100 c heatsink temp. th from 60 c to 100 c parameter in 10 c steps parameter in 10 c steps figure 7. per phase figure 8. per phase typical available output current typical available electric output power as a function as a function of fsw and voutpk/vin of heatsink temperature fullwave iout=f(fsw,voutpk/vin) fullwave pout=f(th) conditions: tj=tjmax conditions: tj=tjmax vout 230 v dc link= 400 v dc link= 400 v switching freq. fsw from 4 khz to 32 khz th= 80 c parameter in * 2 steps th=60c th=100c 0 10 20 30 40 50 60 70 0,1 0,2 0,3 0,4 0,5 0,6 0,7 0,8 0,9 1,0 voutpk/vout iout(a) "from" khz "to" khz 6 7 8 9 10 11 12 13 14 60 65 70 75 80 85 90 95 100 th ( o c) pout (kw) th=60c th=100c 0 10 20 30 40 50 60 1 10 100 f sw (khz) iout (a) 2 4 8 16 32 64 0,10 0,20 0,30 0,40 0,50 0,60 0,70 0,80 0,90 1,00 iout (a) 50,0-54,0 46,0-50,0 42,0-46,0 38,0-42,0 34,0-38,0 30,0-34,0 voutpk/vin fsw (khz) 5 revis ion: 1 copyright by vincotech
10-FZ06BIA041FS01-P898E10 preliminary datasheet figure 9. per phase figure 10. per phase typical efficiency typical efficiency as a function of output power as a function of output power fullwave efficiency=f(pout) 0 efficiency=f(pout) conditions: tj=tjmax conditions: tj=tjmax vout 230 v dc link= 400 v vout 110 v dc link= 400 v switching freq. fsw from 4 khz to 32 khz switching freq. fsw from 4 khz to 32 khz parameter in * 2 steps parameter in * 2 steps "from" khz "to" khz 98,00 98,25 98,50 98,75 99,00 99,25 99,50 99,75 100,00 02468101214 pout (kw) efficiency (%) "from" khz "to" khz 96,00 96,25 96,50 96,75 97,00 97,25 97,50 97,75 98,00 98,25 98,50 98,75 99,00 024681012 pout (kw) efficiency (%) 6 revisi on: 1 copyright by vincotech
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