SKiM406GD066HD Absolute Maximum Ratings Symbol Conditions Values Unit IGBT VCES IC Tj = 175 °C 600 V Ts = 25 °C 468 A Ts = 70 °C 374 A 400 A ICnom ICRM VGES SKiM® 63 tpsc Trench IGBT Modules SKiM406GD066HD Tj ICRM = 2xICnom VCC = 360 V VGE ≤ 15 V VCES ≤ 600 V 800 A -20 ... 20 V 6 µs -40 ... 175 °C Ts = 25 °C 360 A Ts = 70 °C 281 A 400 A Tj = 150 °C Inverse diode IF Tj = 175 °C IFnom Features • IGBT 3 Trench Gate Technology • Solderless sinter technology • VCE(sat) with positive temperature coefficient • Low inductance case • Isolated by Al2O3 DCB (Direct Copper Bonded) ceramic substrate • Pressure contact technology for thermal contacts • Spring contact system to attach driver PCB to the control terminals • High short circuit capability, self limiting to 6 x IC • Integrated temperature sensor Typical Applications* • Automotive inverter • High reliability AC inverter wind • High reliability AC inverter drives Remarks • Case temperature limited to Ts = 125°C max; Tc = Ts (for baseplateless modules) • Recommended Top = -40 … +150°C IFRM IFRM = 2xIFnom 800 A IFSM tp = 10 ms, sin 180°, Tj = 25 °C 2340 A -40 ... 175 °C Tj Module It(RMS) Tterminal = 80 °C Tstg Visol AC sinus 50 Hz, t = 1 min 700 A -40 ... 125 °C 2500 V Characteristics Symbol IGBT VCE(sat) VCE0 rCE Conditions IC = 400 A VGE = 15 V chiplevel VGE = 15 V min. typ. max. Unit Tj = 25 °C 1.45 1.85 V Tj = 150 °C 1.70 2.10 V Tj = 25 °C 0.9 1 V Tj = 150 °C 0.85 0.9 V Tj = 25 °C 1.4 2.1 m Tj = 150 °C VGE(th) VGE=VCE, IC = 6.4 mA ICES VGE = 0 V VCE = 600 V Cies Coes Cres VCE = 25 V VGE = 0 V QG VGE = - 8 V...+ 15 V RGint Tj = 25 °C td(on) tr Eon td(off) tf Eoff Rth(j-s) VCC = 300 V IC = 400 A RG on = 3 RG off = 5 di/dton = 5900 A/µs di/dtoff = 6000 A/µs Tj = 25 °C 5 2.1 3.0 m 5.8 6.5 V 0.1 0.3 mA Tj = 150 °C mA f = 1 MHz 24.64 nF f = 1 MHz 1.54 nF f = 1 MHz 0.73 nF 3200 nC 0.5 Tj = 150 °C 180 ns Tj = 150 °C 80 ns Tj = 150 °C 8 mJ Tj = 150 °C 950 ns Tj = 150 °C 50 ns Tj = 150 °C 25 per IGBT mJ 0.135 K/W GD © by SEMIKRON Rev. 5 – 23.07.2013 1 SKiM406GD066HD Characteristics Symbol Conditions Inverse diode VF = VEC IF = 400 A VGE = 0 V chiplevel VF0 rF SKiM® 63 IRRM Trench IGBT Modules SKiM406GD066HD Qrr Err Rth(j-s) • IGBT 3 Trench Gate Technology • Solderless sinter technology • VCE(sat) with positive temperature coefficient • Low inductance case • Isolated by Al2O3 DCB (Direct Copper Bonded) ceramic substrate • Pressure contact technology for thermal contacts • Spring contact system to attach driver PCB to the control terminals • High short circuit capability, self limiting to 6 x IC • Integrated temperature sensor typ. max. Unit Tj = 25 °C 1.5 1.8 V Tj = 150 °C 1.6 1.8 V Tj = 25 °C 1 1.1 V Tj = 150 °C 0.85 0.95 V Tj = 25 °C 1.3 1.7 m 1.8 2.2 m Tj = 150 °C IF = 400 A Tj = 150 °C di/dtoff = 5900 A/µs T = 150 °C j VGE = -15 V T j = 150 °C VCC = 300 V per diode 350 A 49 µC 12 mJ 0.243 K/W Module LCE RCC'+EE' Features min. 9 terminal-chip 13 nH Ts = 25 °C 0.3 m Ts = 125 °C 0.5 m 761 g w Temperature Sensor R100 TSensor = 100 °C (R25 = 5 k) 339 B100/125 R(T) = R100exp[B100/125(1/T-1/373)]; T[K]; 4096 K Typical Applications* • Automotive inverter • High reliability AC inverter wind • High reliability AC inverter drives Remarks • Case temperature limited to Ts = 125°C max; Tc = Ts (for baseplateless modules) • Recommended Top = -40 … +150°C GD 2 Rev. 5 – 23.07.2013 © by SEMIKRON SKiM406GD066HD Fig. 1: Typ. output characteristic, inclusive RCC'+ EE' Fig. 2: Rated current vs. temperature IC = f (TC) Fig. 3: Typ. turn-on /-off energy = f (IC) Fig. 4: Typ. turn-on /-off energy = f (RG) Fig. 5: Typ. transfer characteristic Fig. 6: Typ. gate charge characteristic © by SEMIKRON Rev. 5 – 23.07.2013 3 SKiM406GD066HD Fig. 7: Typ. switching times vs. IC Fig. 8: Typ. switching times vs. gate resistor RG Fig. 9: Typ. transient thermal impedance Fig. 10: Typ. CAL diode forward charact., incl. RCC'+EE' Fig. 11: Typ. CAL diode peak reverse recovery current Fig. 12: Typ. CAL diode recovery charge 4 Rev. 5 – 23.07.2013 © by SEMIKRON SKiM406GD066HD SKIM 63 GD This is an electrostatic discharge sensitive device (ESDS), international standard IEC 60747-1, Chapter IX * The specifications of our components may not be considered as an assurance of component characteristics. Components have to be tested for the respective application. Adjustments may be necessary. The use of SEMIKRON products in life support appliances and systems is subject to prior specification and written approval by SEMIKRON. We therefore strongly recommend prior consultation of our staff. © by SEMIKRON Rev. 5 – 23.07.2013 5