CMHC-R CMHC-R I C A V CES V -element in a Pack Insulated Type LPT-IGBT / Soft Recovery Diode AlSiC Baseplate APPLICATION Traction drives, High Reliability Converters / Inverters, DC choppers OUTLINE DRAWING & CIRCUIT DIAGRAM Dimensions in mm December HVM--D
CMHC-R MAXIMUM RATINGS Symbol Item Conditions Ratings Unit V CES Collector-emitter voltage V GE = V, T j = - + C V GE = V, T j = C V V GES Gate-emitter voltage V CE = V, T j = C ± V I C DC, T c = 9 C A Collector current I CRM Pulse (Note ) A I E DC A Emitter current (Note ) I ERM Pulse (Note ) A P tot Maximum power dissipation (Note ) T c = C, IGBT part W V iso Isolation voltage RMS, sinusoidal, f = Hz, t = min. V V e Partial discharge extinction voltage RMS, sinusoidal, f = Hz, Q PD pc V T j unction temperature ~ + C T jop Operating junction temperature ~ + C T stg Storage temperature ~ + C t psc Short circuit pulse width V CC = V, V CE V CES, V GE =V, T j = C s ELECTRICAL CHARACTERISTICS Symbol Item Conditions Limits Min Typ Max Unit T j = C. I CES Collector cutoff current V CE = V CES, V GE = V T j = C. ma T j = C. V GE(th) Gate-emitter threshold voltage V CE = V, I C = ma, T j = C... V I GES Gate leakage current V GE = V GES, V CE = V, T j = C.. µa C ies Input capacitance. nf V CE = V, V GE = V, f = khz C oes Output capacitance. nf T j = C C res Reverse transfer capacitance. nf Q G Total gate charge V CC = V, I C = A, V GE = ±V. µc V CEsat t d(on) t r E on(%) E on t d(off) t f E off(%) E off Collector-emitter saturation voltage Turn-on delay time Turn-on rise time Turn-on switching energy Turn-on switching energy Turn-off delay time Turn-off fall time Turn-off switching energy Turn-off switching energy (Note ) (Note ) (Note ) (Note ) (Note ) I C = A V GE = V V CC = V I C = A V GE = ± V R G(on) =. Ω L s = nh V CC = V I C = A V GE = ± V R G(off) =. Ω L s = nh T j = C. T j = C.. T j = C. T j = C. T j = C.9. T j = C.9. T j = C. T j = C.. T j = C.. T j = C. T j = C. T j = C. T j = C. T j = C.9 T j = C. T j = C. T j = C.. T j = C.. T j = C. T j = C.. T j = C.. T j = C. T j = C. T j = C. T j = C. T j = C. T j = C. V December (HVM--D)
CMHC-R ELECTRICAL CHARACTERISTICS (continuation) Symbol Item Conditions V EC t rr I rr Q rr E rec(%) E rec Emitter-collector voltage Reverse recovery time Reverse recovery current Reverse recovery charge Reverse recovery energy Reverse recovery energy (Note ) (Note ) I E = A V GE = V (Note ) (Note ) (Note ) (Note ) (Note ) (Note ) (Note ) V CC = V I C = A V GE = ± V R G(on) =. Ω L s = nh Limits Min Typ Max T j = C. T j = C.. T j = C. T j = C. T j = C. T j = C. T j = C T j = C T j = C T j = C T j = C T j = C T j = C. T j = C. T j = C. T j = C. T j = C. T j = C. Unit V A µc THERMAL CHARACTERISTICS Limits Symbol Item Conditions Unit Min Typ Max R th(j-c)q unction to Case, IGBT part. K/kW Thermal resistance R th(j-c)d unction to Case, FWDi part. K/kW R th(c-s) Contact thermal resistance Case to heat sink, grease = W/m k, D (c-s) = m. K/kW MECHANICAL CHARACTERISTICS Symbol Item Conditions Limits Min Typ Max Unit M t M : Main terminals screw.. N m M s Mounting torque M : Mounting screw.. N m M t M : Auxiliary terminals screw.. N m m Mass. kg CTI Comparative tracking index d a Clearance 9. mm d s Creepage distance. mm L P CE Parasitic stray inductance. nh R CC +EE Internal lead resistance T C = C. mω r g Internal gate resistance T C = C. Ω Note. Pulse width and repetition rate should be such that junction temperature (T j ) does not exceed T opmax rating( C).. The symbols represent characteristics of the anti-parallel, emitter to collector free-wheel diode (FWD i ).. unction temperature (T j ) should not exceed T jmax rating ( C).. Pulse width and repetition rate should be such as to cause negligible temperature rise.. E on(%) / E off(%) / E rec(%) are the integral of.v CE x.i C x dt.. Definition of all items is according to IEC, unless otherwise specified. December (HVM--D)
CMHC-R OUTPUT CHARACTERISTICS (TYPICAL) TRANSFER CHARACTERISTICS (TYPICAL) Tj = C VCE = VGE V GE = 9V V GE = V V GE = V VGE = V V GE = 9V Tj = C Tj = C Collector - Emitter Voltage [V] Gate - Emitter Voltage [V] COLLECTOR-EMITTER SATURATION VOLTAGE FREE-WHEEL DIODE FORWARD VGE = V Tj = C Tj = C Tj = C Tj = C Emitter Current [A] Tj = C Tj = C Collector-Emitter Saturation Voltage [V] Emitter-Collector Voltage [V] December (HVM--D)
CMHC-R CAPACITANCE CHARACTERISTICS (TYPICAL) GATE CHARGE CHARACTERISTICS (TYPICAL) Cies VCE = V, IC = A Tj = C Capacitance [nf] Coes Cres Gate-Emitter Voltage [V] - VGE = V, Tj = C f = khz. Collector-Emitter Voltage [V] - - Gate Charge [µc] HALF-BRIDGE SWITCHING ENERGY HALF-BRIDGE SWITCHING ENERGY Switching Energies [/pulse] VCC = V, VGE = ±V RG(on) =.Ω, RG(off) =.Ω L S = nh, Tj = C Eon Eoff Erec Switching Energies [/pulse] VCC = V, VGE = ±V RG(on) =.Ω, RG(off) =.Ω L S = nh, Tj = C Eon Eoff Erec December (HVM--D)
CMHC-R HALF-BRIDGE SWITCHING ENERGY HALF-BRIDGE SWITCHING ENERGY VCC = V, IC = A VGE = ±V, L S = nh Tj = C, VCC = V, IC = A VGE = ±V, L S = nh Tj = C, Switching Energies [/pulse] Eon Erec Eoff Switching Energies [/pulse] Eon Erec Eoff Gate resistor [Ohm] Gate resistor [Ohm] HALF-BRIDGE SWITCHING TIME HALF-BRIDGE SWITCHING TIME V CC = V, V GE = ±V RG(on) =.Ω, RG(off) =.Ω L S = nh, Tj = C V CC = V, V GE = ±V R G(on) =.Ω, R G(off) =.Ω L S = nh, Tj = C Switching Times []. tf td(off) td(on) Switching Times []. tr td(off) td(on) tr tf.. December (HVM--D)
CMHC-R FREE-WHEEL DIODE REVERSE RECOVERY V CC = V, V GE = ±V RG(on) =.Ω, LS = nh Tj = C, FREE-WHEEL DIODE REVERSE RECOVERY V CC = V, V GE = ±V RG(on) =.Ω, LS = nh Tj = C, Reverse Recovery Time [] Irr trr Reverse Recovery Current [A] Reverse Recovery Time [] Irr trr Reverse Recovery Current [A]. Emitter Current [A]. Emitter Current [A] Normalized Transient Thermal impedance..... TRANSIENT THERMAL IMPEDANCE CHARACTERISTICS R th(j-c)q =.K/kW Rth(j-c)D =.K/kW... Time [s] n t Z ( t ) ( ) exp i th j c Ri i R i [K/kW] :.9.9..9 i [sec] :.... December (HVM--D)
CMHC-R REVERSE BIAS SAFE OPERATING AREA (RBSOA) VCC V, VGE = ±V Tj = C, RG(off) =.Ω SHORT CIRCUIT SAFE OPERATING AREA (SCSOA) V CC V, V GE = ±V R G(on) =.Ω, R G(off) =.Ω Tj = C Collector Current [ka] Collector-Emitter Voltage [V] Collector-Emitter Voltage [V] FREE-WHEEL DIODE REVERSE RECOVERY SAFE OPERATING AREA (RRSOA) VCC V, di/dt < 9kA/ Tj = C Reverse Recovery Current [A] Emitter-Collector Voltage [V] December (HVM--D)
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