Data Sheet, Doc. No. 5SYA 1449- Aug 16 5SNG 1X173 PRELIMINARY LinPak phase leg IGBT module VCE = 17 V IC = 2 x 1 A Ultra low inductance phase-leg module Compact design with very high current density Paralleling without derating AlSiC base-plate for high power cycling capability AlN substrate for low thermal resistance Low-loss, fast and rugged SPT++ chip-set Maximum rated values 1) Parameter Symbol Conditions min max Unit Collector-emitter voltage VCES VGE = V, Tvj 25 C 17 V DC collector current IC TC = 1 C, Tvj = 1 A Peak collector current ICM tp = 1 ms 2 A Gate-emitter voltage VGES -2 2 V Total power dissipation Ptot TC = 25 C, Tvj = 55 W DC forward current IF 1 A Peak forward current IFRM tp = 1 ms 2 A Surge current IFSM VR = V, Tvj =, tp = 1 ms, half-sinewave 6 A IGBT short circuit SOA tpsc VCC = 13 V, VCEM CHIP 17 V 1 µs VGE 15 V, Tvj Isolation voltage Visol 1 min, f = 5 Hz 4 V Junction temperature Tvj -5 Junction operating temperature Tvj(op) -5 Case temperature TC -5 15 C Storage temperature Tstg -5 Ms Base-heatsink, M6 screws 4 6 Mounting torques 2) Mt1 Main terminals, M8 screws 8 1 Mt2 Auxiliary terminals, M4 screws.6.8 Nm 1) Maximum rated values indicate limits beyond which damage to the device may occur per IEC 6747 2) For detailed mounting instructions refer to ABB Document No. 5SYA 239
IGBT characteristic values 3) Collector (-emitter) breakdown voltage Collector-emitter 4) saturation voltage V(BR)CES VGE = V, IC = 1 ma, Tvj = 25 C 17 V VCE sat IC = 1 A, VGE Collector cut-off current ICES VCE = 17 V, VGE = V Tvj = 25 C 2.25 V Tvj = 2.55 V Tvj = 2.75 V Tvj = 25 C.3 ma Tvj = 2. ma Tvj = Gate leakage current IGES VCE = V, VGE = 2 V, Tvj = -5 5 na Gate-emitter threshold voltage VGE(TO) IC = 4 ma, VCE = VGE, Tvj = 25 C 5.9 V Gate charge Qge IC = 1 A, VCE = 9 V, VGE = -15 V..15 V 5.3 µc Input capacitance Cies 61 nf Output capacitance Coes VCE = 25 V, VGE = V, f = 1 MHz, Tvj = 25 C 5.2 nf Reverse transfer capacitance Cres 5.3 nf Turn-on delay time Rise time Turn-off delay time Fall time Turn-on switching energy Turn-off switching energy Short circuit current td(on) tr td(off) tf Eon Eoff 3) Characteristic values according to IEC 6747 9 4) Collector-emitter saturation voltage is given at chip level ISC VCC = 9 V, IC = 1 A, RG =.39, CGE = nf, VGE = 15 V, L = 2 nh, inductive load VCC = 9 V, IC = 1 A, RG =.56, CGE = nf, VGE = 15 V, L = 2 nh, inductive load VCC = 9 V, IC = 1 A, RG =.39, CGE = nf, VGE = ±15 V, L = 2 nh, inductive load VCC = 9 V, IC = 1 A, RG =.56, CGE = nf, VGE = ±15 V, L = 2 nh, inductive load tpsc 1 µs, VGE, VCC = 13 V, VCEM CHIP 17 V 6 (tbd) Tvj = 25 C 275 ns Tvj = 29 ns Tvj = 31 ns Tvj = 25 C 8 ns Tvj = 95 ns Tvj = 1 ns Tvj = 25 C 58 ns Tvj = 66 ns Tvj = 71 ns Tvj = 25 C 9 ns Tvj = 11 ns Tvj = 12 ns ma Tvj = 25 C 25 mj Tvj = 45 mj Tvj = 57 mj Tvj = 25 C 19 mj Tvj = 27 mj Tvj = 34 mj Tvj = 3 A 2 5SNG 1X173 Doc. No. 5SYA 1449-8-216
Diode characteristic values 5) Tvj = 25 C 1.6 V Forward voltage 6) VF IF = 1 A Tvj = 1.75 V Tvj = 1.7 V Tvj = 25 C 17 A Peak reverse recovery current IRM Tvj = 11 A Tvj = 115 A Tvj = 25 C 27 µc Recovered charge Reverse recovery time Qrr trr VCC = 9 V, IF = 1 A, VGE = 15 V, RG =.39, CGE = nf, L = 2 nh, inductive load Tvj = 41 µc Tvj = 48 µc Tvj = 25 C 52 ns Tvj = 8 ns Tvj = 9 ns Tvj = 25 C 15 mj Reverse recovery energy Erec Tvj = 23 mj Tvj = 27 mj 5) Characteristic values according to IEC 6747 2 6) Forward voltage is given at chip level NTC Thermistor Rated resistor R25 4.45 kω B-value B25/85 R2 = R25 exp [B25/85(1/T2 1/(298.15K))] 3213 K B25/1 R2 = R25 exp [B25/1(1/T2 1/(298.15K))] 3348 K Package properties 7) IGBT thermal resistance junction to case Diode thermal resistance junction to case IGBT thermal resistance 2) case to heatsink Diode thermal resistance 2) case to heatsink Rth(j-c)IGBT 27 K/kW Rth(j-c)DIODE 45 K/kW Rth(c-s)IGBT IGBT per switch, grease = 1W/m x K 27 K/kW Rth(c-s)DIODE Diode per switch, grease = 1W/m x K 33 K/kW Comparative tracking index CTI 6 Module stray inductance Lσ CE per switch 3 nh TC = 25 C.17 Resistance, terminal-chip RCC +EE per switch TC =.24 TC =.27 mω 2) For detailed mounting instructions refer to ABB Document No. 5SYA 239 Mechanical properties 7) Dimensions L x W x H Typical 14 x 1 x 38 mm Clearance distance in air da according to IEC 6664-1 and EN 5124-1 Term. to base: 2 Term. to term: 7 mm Surface creepage distance ds according to IEC 6664-1 and EN 5124-1 Term. to base: 3 Term. to term: 3 mm Mass m 82 g 7) Package and mechanical properties according to IEC 6747 15 3 5SNG 1X173 Doc. No. 5SYA 1449-8-216
Electrical configuration Outline drawing 2) Note: all dimensions are shown in millimeters 2) For detailed mounting instructions refer to ABB Document No. 5SYA 239 This is an electrostatic sensitive device, please observe the international standard IEC 6747-1, chap. VIII. This product has been designed and qualified for Industrial Level. 4 5SNG 1X173 Doc. No. 5SYA 1449-8-216
2 2 25 C 15 15 1 1 5 5 25 C 1 2 3 4 5 5 6 7 8 9 1 11 12 13 14 15 Fig. 1 Typical on-state characteristics, chip level Fig. 2 Typical transfer characteristics, chip level 2 = 25 C 2 15 15 1 5 19 V 17 V 15 V 13 V 11 V 9 V 1 5 19 V 17 V 15 V 13 V 11 V 9 V 1 2 3 4 5 = 1 2 3 4 5 6 Fig. 3 Typical output characteristics, chip level Fig. 4 Typical output characteristics, chip level 5 5SNG 1X173 Doc. No. 5SYA 1449-8-216
3. 2.5 2. = 9 V on =.39 off =.56 = nf = 125, = 2 nh 1.2 1..8 E on = 9 V = 1 A = nf = 125, = 2 nh E on, E off in J 1.5 E on E on, E off in J.6 1..4 E off E off.5. 5 1 15 2.2. 2 4 6 8 1 in Fig. 5 Typical switching energies per pulse vs. collector current Fig. 6 Typical switching energies per pulse vs. gate resistor t d(on), t r, t d(off), t f in µs 1.1 t d(off) t d(on) t f t r = 9 V on =.39 off =.56 = nf = = 2 nh.1 5 1 15 2 t d(on), t r, t d(off), t f in µs = 9 V = 1 A = nf = = 2 nh 1 t d(off) t d(on) t r t f.1 2 4 6 8 1 in Fig. 7 Typical switching times vs. collector current Fig. 8 Typical switching times vs. gate resistor 6 5SNG 1X173 Doc. No. 5SYA 1449-8-216
1 3 = V 2 f OSC = 1 MHz V OSC = 5 mv 15 = 13 V 1 1 2 C ies 5 = 9 V C in nf C oes 1 1 C res -5-1 1 5 1 15 2 25 3 35-15 1 2 3 4 5 6 7 Q G in µc Fig. 9 Typical capacitances vs. collector-emitter voltage Fig. 1 Typical gate charge characteristics 2.5 2. chip module 1.5 pulse / 1..5 13 V, = -5.. = ±15 V, =.56. 5 1 15 2 Fig. 11 Turn-off safe operating area (RBSOA) 7 5SNG 1X173 Doc. No. 5SYA 1449-8-216
E rec in mj, I RM, Q rr in µc 15 125 1 75 5 I RM Q rr = 9 V on =.39 = nf = 125, = 2 nh E rec in mj, I RM, Q rr in µc 15 125 1 75 5 = 9 V I c = 1 A = nf = 125, = 2 nh I RM = 3.3 = 2.2 = 1.5 =.82 =.56 =.39 =.33 =.27 Q rr 25 25 E rec E rec 5 1 15 2 I F 2 4 6 8 1 12 di/dt in ka/µs Fig. 12 Typical reverse recovery characteristics vs. forward current Fig. 13 Typical reverse recovery characteristics vs. di/dt 2 15 2 15 13 V di/dt 15 ka/ s = -5.. = 2 nh I F 1 25 C I R 1 5 5 1 2 V F 5 1 15 2 V R Fig. 14 Typical diode forward characteristics chip level Fig. 15 Safe operating area diode (SOA) 8 5SNG 1X173 Doc. No. 5SYA 1449-8-216
1 2 Analytical function for transient thermal impedance: Z th(j-c) in K/kW IGBT, DIODE 1 1 Z th(j-c) Diode Z th(j-c) IGBT DIODE IGBT Z th (j-c) (t) = n i 1 R i (1- e -t/ i i 1 2 3 4 5 Ri(K/kW) 15. 6.48 5.58 i(ms) 62.9 128 2.55 Ri(K/kW) 26.3 1. 8.96 i(ms) 57.6 3.42 929 ) Fig. 16 1 1-3 1-2 1-1 1 1 1 t in s Thermal impedance vs. time Related documents: 5SYA 242 Failure rates of HiPak modules due to cosmic rays 5SYA 243 Load cycle capability of HiPaks 5SYA 245 Thermal runaway during blocking 5SYA 253 Applying IGBT 5SYA 257 IGBT diode safe operating area (SOA) 5SYA 258 Surge currents for IGBT diodes 5SYA 293 Thermal design of IGBT modules 5SYA 298 Paralleling of IGBT modules 5SZK 9111 Specification of environmental class for HiPak Storage 5SZK 9112 Specification of environmental class for HiPak Transportation 5SZK 9113 Specification of environmental class for HiPak Operation (Industry) 5SZK 912 Specification of environmental class for HiPak ABB Switzerland Ltd. Semiconductors Fabrikstrasse 3 CH-56 Lenzburg Switzerland Phone: +41 58 586 1419 Fax: +41 58 586 136 E-Mail: abbsem@ch.abb.com Internet: www.abb.com/semiconductors We reserve the right to make technical changes or to modify the contents of this document without prior notice. We reserve all rights in this document and the information contained therein. Any reproduction or utilization of this document or parts thereof for commercial purposes without our prior written consent is forbidden. Any liability for use of our products contrary to the instructions in this document is excluded. 5SNG 1X173 Doc. No. 5SYA 1449-8-216