< IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE Collector current I C .......................................... 75A Collector-emitter voltage V CES ......................... 1 2 0 0 V Maximum junction temperature T j m a x .............. 1 7 5 C Flat base Type Copper base plate (non-plating) Tin plating pin terminals RoHS Directive compliant CIB (Converter+Inverter+Chopper Brake) Recognized under UL1557, File E323585 APPLICATION AC Motor Control, Motion/Servo Control, Power supply, etc. OUTLINE DRAWING & INTERNAL CONNECTION Dimension in mm TERMINAL t=0.8 SECTION A INTERNAL CONNECTION Tolerance otherwise specified P(54~56) P1(48~49) Division of Dimension GUP(13) R(1~2) GVP(18) GWP(23) B(52~53) S(5~6) V(19~20) U(14~15) T(9~10) W(24~25) GUN(40) N(59~61) GVN(33) GWN(31) NTC TH1(29) GB(41) N1(44~45) Es(32) Es'(39) Caution: Each (two or three) pin terminal of P/N/P1/N1/U/V/W/B/R/S/T is connected in the module, but should use all each three pins for the external wiring. Publication Date : June.2011 1 TH2(28) 3 Tolerance 0.5 to over 3 to 6 0.3 over 6 to 30 0.5 ClampDi 0.2 over 30 to 120 0.8 over 120 to 400 1.2 The tolerance of size between terminals is assumed to be 0.4. < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE ABSOLUTE MAXIMUM RATINGS (Tj=25 C, unless otherwise specified) INVERTER PART IGBT/FWDi Symbol Item VCES Collector-emitter voltage VGES Gate-emitter voltage IC Ptot IE IERM (Note.1) Tjmax Unit 1200 V C-E short-circuited 20 V (Note.2, 4) Emitter current A 150 TC=25 C (Note.2, 4) 600 TC=25 C (Note.2, 4) 75 (Note.3) Pulse, Repetitive Maximum junction temperature 75 (Note.3) Pulse, Repetitive Total power dissipation (Note.1) Conditions DC, TC=122 C Collector current ICRM Rating G-E short-circuited W A 150 - 175 C BRAKE PART IGBT/CLAMPDi Rating Unit VCES Symbol Collector-emitter voltage G-E short-circuited 1200 V VGES Gate-emitter voltage C-E short-circuited 20 V IC ICRM Item Conditions DC, TC=125 C Collector current (Note.2, 4) Total power dissipation TC=25 C VRRM Repetitive peak reverse voltage G-E short-circuited IFRM Tjmax TC=25 C Forward current (Note.2, 4) Pulse, Repetitive Maximum junction temperature A 100 (Note.2, 4) Ptot IF 50 (Note.3) Pulse, Repetitive 425 W 1200 V 50 (Note.3) A 100 - 175 C CONVERTER PART Di Rating Unit VRRM Symbol Repetitive peak reverse voltage - 1600 V Ea Recommended AC input voltage RMS 440 V IO DC output current 3-phase full wave rectifying, TC=125 C 75 A Surge forward current The sine half wave 1 cycle peak value, f=60 Hz, non-repetitive 750 A I t Current square time Value for one cycle of surge current 2340 As Tjmax Maximum junction temperature - 150 C Rating Unit 125 C IFSM 2 Item Conditions (Note.2) 2 MODULE Symbol Item Conditions TCmax Maximum case temperature (Note.2) Tjop Operating junction temperature - -40 ~ +150 Tstg Storage temperature - -40 ~ +125 Visol Isolation voltage Terminals to base plate, RMS, f=60 Hz, AC 1 min 2500 C V MECHANICAL CHARACTERISTICS Symbol Ms Item Mounting torque Limits Conditions Mounting to heat sink Typ. Max. 2.5 3.0 3.5 Terminal to terminal 6.47 - - Terminal to base plate 14.27 - - ds Creepage distance da Clearance m Weight - ec Flatness of base plate On the centerline X, Y M 5 screw Min. Unit N*m mm Terminal to terminal 6.47 - - Terminal to base plate 12.33 - - - 300 - g 0 - +100 m Publication Date : June.2011 2 (Note.5) mm < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE ELECTRICAL CHARACTERISTICS (T j =25 C, unless otherwise specified) INVERTER PART IGBT/FWDi Symbol Item Limits Conditions Min. Typ. Max. Unit ICES Collector-emitter cut-off current VCE=VCES, G-E short-circuited - - 1.0 mA IGES Gate-emitter leakage current VGE=VGES, C-E short-circuited - - 0.5 A VGE(th) Gate-emitter threshold voltage IC=7.5 mA, VCE=10 V 5.4 6.0 6.6 V IC=75 A VCEsat Collector-emitter saturation voltage Cies Input capacitance Coes Output capacitance Cres Reverse transfer capacitance QG Gate charge td(on) Turn-on delay time tr Rise time td(off) Turn-off delay time tf Fall time T j =25 C - 1.80 2.25 VGE=15 V, T j =125 C - 2.00 - (Terminal) T j =150 C - 2.05 - IC=75 A (Note.1) (Note.6) , T j =25 C - 1.70 2.15 VGE=15 V, T j =125 C - 1.90 - (Chip) T j =150 C - 1.95 - , - - 7.5 - - 1.5 - - 0.13 - 175 - - - 300 VCE=10 V, G-E short-circuited VCC=600 V, IC=75 A, VGE=15 V VCC=600 V, IC=75 A, VGE=15 V, RG=8.2 , Inductive load Emitter-collector voltage - - 200 - - 600 - - 300 T j =25 C - 1.80 2.25 G-E short-circuited, T j =125 C - 1.80 - (Terminal) T j =150 C - 1.80 - T j =25 C - 1.70 2.15 G-E short-circuited, T j =125 C - 1.70 - (Chip) T j =150 C - 1.70 - IE=75 A VEC (Note.6) IE=75 A (Note.6) (Note.6) , , V V nF nC ns V V trr (Note.1) Reverse recovery time VCC=600 V, IE=75 A, VGE=15 V, - - 300 ns Qrr (Note.1) Reverse recovery charge RG=8.2 , Inductive load - 4.0 - C Eon Turn-on switching energy per pulse VCC=600 V, IC=IE=75 A, - 7.3 - Eoff Turn-off switching energy per pulse VGE=15 V, RG=8.2 , T j =150 C, - 8.0 - Reverse recovery energy per pulse Inductive load - 6.9 - mJ - - 4.0 m - 0 - Err (Note.1) R CC'+EE' Internal lead resistance rg Internal gate resistance Main terminals-chip, per switch, (Note.2) TC=25 C Per switch mJ BRAKE PART IGBT/CLAMPDi Symbol ICES Item Collector-emitter cut-off current VCE=VCES, G-E short-circuited IGES Gate-emitter leakage current VGE=VGES, C-E short-circuited VGE(th) Gate-emitter threshold voltage IC=5 mA, VCE=10 V Collector-emitter saturation voltage Cies Input capacitance Coes Output capacitance Cres Reverse transfer capacitance QG Gate charge Unit Min. Typ. Max. - - 1.0 mA - - 0.5 A 5.4 6.0 6.6 V T j =25 C - 1.80 2.25 VGE=15 V, T j =125 C - 2.00 - (Terminal) T j =150 C - 2.05 - IC=50 A VCEsat Limits Conditions IC=50 A (Note.6) (Note.6) , T j =25 C - 1.70 2.15 VGE=15 V, , T j =125 C - 1.90 - (Chip) T j =150 C - 1.95 - - - 5.0 VCE=10 V, G-E short-circuited - - 1.0 - - 0.08 VCC=600 V, IC=50 A, VGE=15 V - 117 - Publication Date : June.2011 3 V V nF nC < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE ELECTRICAL CHARACTERISTICS (cont.; T j =25 C, unless otherwise specified) BRAKE PART IGBT/CLAMPDi Symbol Item td(on) Turn-on delay time tr Rise time td(off) Turn-off delay time tf Fall time VCC=600 V, IC=50 A, VGE=15 V, RG=13 , Inductive load Forward voltage Min. Typ. Max. - - 300 - - 200 - - 600 - - 300 T j =25 C - 1.80 2.25 G-E short-circuited, T j =125 C - 1.80 - (Terminal) T j =150 C - 1.80 - (Note.6) IF=50 A VF Limits Conditions (Note.6) IF=50 A , T j =25 C - 1.70 2.15 G-E short-circuited, , T j =125 C - 1.70 - (Chip) T j =150 C Unit ns V V - 1.70 - trr Reverse recovery time VCC=600 V, IF=50 A, VGE=15 V, - - 300 ns Qrr Reverse recovery charge RG=13 , Inductive load - 2.7 - C Eon Turn-on switching energy per pulse VCC=600 V, IC=IF=50 A, - 5.5 - Eoff Turn-off switching energy per pulse VGE=15 V, RG=13 , T j =150 C, - 5.3 - Err Reverse recovery energy per pulse Inductive load - 4.5 - mJ rg Internal gate resistance - - 0 - mJ CONVERTER PART CONVDi Symbol IRRM VF (Terminal) Item Conditions Repetitive peak reverse current VR=VRRM, T j =150 C IF=75 A Forward voltage (Note.6) Limits Unit Min. Typ. Max. - - 20 mA - 1.2 1.6 V NTC THERMISTOR PART Symbol Item Conditions (Note.2) R25 Zero-power resistance TC=25 C R/R Deviation of resistance TC=100 C, R100=493 B(25/50) B-constant Approximate by equation P25 Power dissipation TC=25 C (Note.7) (Note.2) Limits Max. Unit Min. Typ. 4.85 5.00 5.15 k -7.3 - +7.8 % - 3375 - K - - 10 mW THERMAL RESISTANCE CHARACTERISTICS Symbol Item Conditions Limits Min. Typ. Max. Rth(j-c)Q Junction to case, per Inverter IGBT - - 0.25 Rth(j-c)D Junction to case, per Inverter FWDi - - 0.40 Rth(j-c)Q Thermal resistance (Note.2) Unit K/W Junction to case, per Brake IGBT - - 0.35 Rth(j-c)D Junction to case, per Brake ClampDi - - 0.63 Rth(j-c)D Junction to case, per Converter ConvDi - - 0.24 K/W - 15 - K/kW Rth(c-s) Contact thermal resistance (Note.2) Case to heat sink, per 1 module, Thermal grease applied Publication Date : June.2011 4 (Note.8) K/W < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE -:Concave +:Convex Note.1: Represent ratings and characteristics of the anti-parallel, emitter-collector free wheeling diode (FWDi). 2: Case temperature (TC) and heat sink temperature (T s ) are defined on the each surface (mounting side) of base plate and heat sink just under the chips. Refer to the figure of chip location. 3: Pulse width and repetition rate should be such that the device junction temperature (T j ) dose not exceed T j m a x rating. 4: Junction temperature (T j ) should not increase beyond T j m a x rating. 5: The base plate (mounting side) flatness measurement points (X, Y) are as follows of the following figure. Y X mounting side mounting side -:Concave mounting side +:Convex 6: Pulse width and repetition rate should be such as to cause negligible temperature rise. Refer to the figure of test circuit. R 1 1 7: B ( 25 / 50) ln( 25 ) /( ), R 50 T25 T50 R25: resistance at absolute temperature T25 [K]; T25=25 [C]+273.15=298.15 [K] R50: resistance at absolute temperature T50 [K]; T50=50 [C]+273.15=323.15 [K] 8: Typical value is measured by using thermally conductive grease of =0.9 W/(m*K). 9: Use the following screws when mounting the printed circuit board (PCB) on the stand offs. "M2.6x10 or M2.6x12 self tapping screw" The length of the screw depends on the thickness of the PCB. RECOMMENDED OPERATING CONDITIONS (T a =25 C) Symbol Item VCC (DC) Supply voltage VGEon Gate (-emitter drive) voltage RG External gate resistance Conditions Applied across P-N/P1-N1 terminals Applied across GB-Es1/ G*P-*/G*N-Es(*=U, V, W) terminals Inverter IGBT Per switch Brake IGBT Publication Date : June.2011 5 Limits Unit Min. Typ. Max. - 600 850 V 13.5 15.0 16.5 V 8.2 - 82 13 - 130 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE CHIP LOCATION (Top view) Dimension in mm, tolerance: 1 mm Tr*P/Tr*N/TrBr: IGBT, Di*P/Di*N: FWDi (*=U/V/W), DiBr: ClampDi, CR*P/CR*N: ConvDi (*=R/S/T), Th: NTC thermistor TEST CIRCUIT AND WAVEFORMS vGE iE 90 % Q rr =0.5xI rr xt r r iE 0V 0 t Load t rr IE -V GE VCC iC 0A + t 90 % RG +V GE VGE 0V Irr VCE iC 10% -V GE 0A tr t d (o n ) tf t d( o ff) t Switching characteristics test circuit and waveforms t r r , Q r r test waveform iE vCE 0 iC iC ICM VCC 0.1xICM 0.1xVCC 0.5xI r r ICM VCC t 0 0.1xVCC IEM vEC vCE 0.02xICM ti ti IGBT Turn-on switching energy IGBT Turn-off switching energy t VCC 0A t 0V t ti FWDi Reverse recovery energy Turn-on / Turn-off switching energy and Reverse recovery energy test waveforms (Integral time instruction drawing) Publication Date : June.2011 6 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE TEST CIRCUIT 48/49 VGE=15 V 48/49 IC 13 VGE=15 V 14/15 VGE=15 V IC 18 Shortcircuited 40 P1 44/45 GWP V Es G-E short-circuited IF V V V VGE=15 V Es GVP-V, GVN-Es, GWP-W, GWN-Es, GB-Es G-E short-circuited UP / UN IGBT 52/53 W VGE=15 V IC GVN N1 48/49 Shortcircuited U IC V P1 GVP GUN N1 Es 44/45 32 Shortcircuited GUP IC GB 31 P1 Shortcircuited VGE=15 V VGE=15 V Shortcircuited 32 B V 33 44/45 V 24/25 V Shortcircuited 32 IC 23 19/20 V P1 48/49 IC GWN N1 41 N1 Es G-E short-circuited GUP-U, GUN-Es, GWP-W, GWN-Es, GB-Es VP / VN IGBT Shortcircuited 44/45 32 GUP-U, GUN-Es, GVP-V, GVN-Es, GB-Es WP / WN IGBT G-E short-circuited GUP-U, GUN-Es, GVP-V, GVN-Es, GWP-W, GWN-Es Brake IGBT / ClampDi V CE s a t / ClampDi VF test circuit V 48/49 Shortcircuited 48/49 IE 13 Shortcircuited 14/15 Shortcircuited IE 18 Shortcircuited V Shortcircuited Shortcircuited 33 44/45 32 P1 31 44/45 32 P1 Shortcircuited GWP V V U GUN Es G-E short-circuited V V IE N1 GVP-V, GVN-Es, GWP-W, GWN-Es, GB-Es UP / UN FWDi P Shortcircuited GVP Shortcircuited 59/60/61 44/45 P1 Shortcircuited GUP IF 1/2 24/25 V 40 32 IE 23 19/20 V 54/55/56 48/49 Shortcircuited G-E short-circuited Shortcircuited IE GVN Es W IE GWN N1 Es GUP-U, GUN-Es, GWP-W, GWN-Es, GB-Es G-E short-circuited VP / VN FWDi V R N1 IF N GUP-U, GUN-Es, GVP-V, GVN-Es, GB-Es WP / WN FWDi ConvDi (ex. phase-R) VEC / ConvDi VF test circuit * In the above test circuit, should use all three main pin terminals (P1/N1/P/N/U/V/W) for connection with the terminals and the current source. Publication Date : June.2011 7 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE PERFORMANCE CURVES INVERTER PART OUTPUT CHARACTERISTICS (TYPICAL) COLLECTOR-EMITTER SATURATION VOLTAGE CHARACTERISTICS (TYPICAL) T j =25 C VGE=15 V (Chip) 150 VGE=20 V 12 V 3 COLLECTOR-EMITTER SATURATION VOLTAGE VCE (V) IC (A) COLLECTOR CURRENT 13.5 V 15 V 125 100 11 V 75 10 V 50 9V 25 T j =150 C T j =125 C 2.5 2 1.5 T j =25 C 1 0.5 0 0 0 2 4 6 8 COLLECTOR-EMITTER VOLTAGE 10 0 VCE (V) T j =25 C 50 100 COLLECTOR CURRENT COLLECTOR-EMITTER SATURATION VOLTAGE CHARACTERISTICS (TYPICAL) 150 IC (A) FREE WHEELING DIODE FORWARD CHARACTERISTICS (TYPICAL) G-E short-circuited (Chip) (Chip) 1000 10 IE (A) IC=150 A 8 IC=75 A 6 EMITTER CURRENT COLLECTOR-EMITTER SATURATION VOLTAGE VCE (V) (Chip) 3.5 IC=30 A 4 2 100 T j =150 C T j =125 C T j =25 C 0 6 8 10 12 14 GATE-EMITTER VOLTAGE 16 18 10 20 0.5 VGE (V) 1 1.5 2 EMITTER-COLLECTOR VOLTAGE Publication Date : June.2011 8 2.5 VEC (V) 3 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE PERFORMANCE CURVES INVERTER PART HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) VCC=600 V, VGE=15 V, RG=8.2 , INDUCTIVE LOAD ---------------: T j =150 C, - - - - -: T j =125 C VCC=600 V, VGE=15 V, IC=75 A, INDUCTIVE LOAD ---------------: T j =150 C, - - - - -: T j =125 C 1000 1000 td(off) tf 100 SWITCHING TIME (ns) SWITCHING TIME (ns) tf td(on) 10 tr td(off) 100 td(on) tr 10 1 1 10 COLLECTOR CURRENT 1 100 IC (A) EXTERNAL GATE RESISTANCE HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) VCC=600 V, VGE=15 V, RG=8.2 , INDUCTIVE LOAD, PER PULSE ---------------: T j =150 C, - - - - -: T j =125 C RG () 100 Eoff 10 Eon SWITCHING ENERGY (mJ) REVERSE RECOVERY ENERGY (mJ) 100 1 100 HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) VCC=600 V, VGE=15 V, IC=75 A, INDUCTIVE LOAD, PER PULSE ---------------: T j =150 C, - - - - -: T j =125 C REVERSE RECOVERY ENERGY (mJ) SWITCHING ENERGY (mJ) 10 10 Eon Eoff 10 Err Err 0.1 1 1 1 10 1 100 10 EXTERNAL GATE RESISTANCE COLLECTOR CURRENT IC (A) EMITTER CURRENT IE (A) Publication Date : June.2011 9 100 RG () < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE PERFORMANCE CURVES INVERTER PART CAPACITANCE CHARACTERISTICS (TYPICAL) FREE WHEELING DIODE REVERSE RECOVERY CHARACTERISTICS (TYPICAL) VCC=600 V, VGE=15 V, RG=8.2 , INDUCTIVE LOAD ---------------: T j =150 C, - - - - -: T j =125 C G-E short-circuited, T j =25 C 100 1000 Cies t r r (ns), I r r (A) CAPACITANCE (nF) 10 Coes 1 0.01 10 0.1 1 10 COLLECTOR-EMITTER VOLTAGE 100 1 VCE (V) 10 EMITTER CURRENT 100 IE (A) GATE CHARGE CHARACTERISTICS (TYPICAL) TRANSIENT THERMAL IMPEDANCE CHARACTERISTICS (MAXIMUM) VCC=600 V, IC=75 A, Tj=25 C Single pulse, TC=25 C R t h ( j - c ) Q =0.25 K/W, R t h ( j - c ) D =0.40 K/W 20 1 NORMALIZED TRANSIENT THERMAL RESISTANCE Zth(j-c) VGE (V) trr Cres 0.1 GATE-EMITTER VOLTAGE Irr 100 15 10 5 0 0 50 100 GATE CHARGE 150 200 250 QG (nC) 0.1 0.01 0.001 0.00001 0.0001 0.001 0.01 TIME (S) Publication Date : June.2011 10 0.1 1 10 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE PERFORMANCE CURVES BRAKE PART COLLECTOR-EMITTER SATURATION VOLTAGE CHARACTERISTICS (TYPICAL) CLAMP DIODE FORWARD CHARACTERISTICS (TYPICAL) VGE=15 V G-E short-circuited (Chip) 3 T j =150 C T j =150 C VF (V) T j =125 C 2.5 FORWARD VOLTAGE COLLECTOR-EMITTER SATURATION VOLTAGE VCEsat (V) (Chip) 100 3.5 2 1.5 T j =25 C 1 10 T j =25 C T j =125 C 0.5 0 1 0 20 40 60 COLLECTOR CURRENT 80 0.5 100 1 IC (A) 1.5 FORWARD CURRENT 2 2.5 IF (A) HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) VCC=600 V, VGE=15 V, RG=13 , INDUCTIVE LOAD ---------------: T j =150 C, - - - - -: T j =125 C VCC=600 V, IC=50 A, VGE=15 V, INDUCTIVE LOAD ---------------: T j =150 C, - - - - -: T j =125 C 1000 1000 td(off) tf 100 SWITCHING TIME (ns) SWITCHING TIME (ns) tf td(on) 10 tr td(off) 100 td(on) tr 1 10 1 10 COLLECTOR CURRENT 10 100 IC (A) 100 EXTERNAL GATE RESISTANCE Publication Date : June.2011 11 1000 RG () < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE PERFORMANCE CURVES BRAKE PART HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) VCC=600 V, VGE=15 V, RG=13 , INDUCTIVE LOAD, PER PULSE ---------------: T j =150 C, - - - - -: T j =125 C HALF-BRIDGE SWITCHING CHARACTERISTICS (TYPICAL) VCC=600 V, IC/IF=50 A, VGE=15 V, INDUCTIVE LOAD, PER PULSE ---------------: T j =150 C, - - - - -: T j =125 C 100 Err SWITCHING ENERGY (mJ) REVERSE RECOVERY ENERGY (mJ) SWITCHING ENERGY (mJ) REVERSE RECOVERY ENERGY (mJ) 10 Eoff 1 Eon 0.1 Eon 10 Eoff Err 1 1 10 100 10 1000 EXTERNAL GATE RESISTANCE COLLECTOR CURRENT IC (A) FORWARD CURRENT IF (A) RG () CLAMP DIODE REVERSE RECOVERY CHARACTERISTICS (TYPICAL) TRANSIENT THERMAL IMPEDANCE CHARACTERISTICS (MAXIMUM) VCC=600 V, VGE=15 V, RG=13 , INDUCTIVE LOAD ---------------: T j =150 C, - - - - -: T j =125 C Single pulse, TC=25 C R t h ( j - c ) Q =0.35 K/W, R t h ( j - c ) D =0.63 K/W 1000 1 100 NORMALIZED TRANSIENT THERMAL RESISTANCE Zth(j-c) t r r (ns), I r r (A) 100 trr Irr 10 1 10 FORWARD CURRENT 100 IF (A) 0.1 0.01 0.001 0.00001 0.0001 0.001 0.01 TIME (S) Publication Date : June.2011 12 0.1 1 10 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE PERFORMANCE CURVES CONVERTER PART CONVERTER DIODE FORWARD CHARACTERISTICS (TYPICAL) TRANSIENT THERMAL IMPEDANCE CHARACTERISTICS (MAXIMUM) Single pulse, TC=25 C R t h ( j - c ) D =0.24 K/W 100 NORMALIZED TRANSIENT THERMAL RESISTANCE Zth(j-c) 1 FORWARD CURRENT IF (A) T j =125 C T j =25 C 10 1 0.4 0.6 0.8 1 FORWARD VOLTAGE 1.2 1.4 1.6 VF (V) 0.1 0.01 0.001 0.00001 0.0001 0.001 0.01 TIME (S) Publication Date : June.2011 13 0.1 1 10 < IGBT MODULES > CM75MXA-24S HIGH POWER SWITCHING USE INSULATED TYPE Keep safety first in your circuit designs! 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(c) 2011 MITSUBISHI ELECTRIC CORPORATION. ALL RIGHTS RESERVED. Publication Date : June.2011 14