VCE = 7 V IC = 24 A ABB HiPak IGBT Module 5SNA 24E7 Low-loss, rugged SPT chip-set Smooth switching SPT chip-set for good EMC Industry standard package High power deity AlSiC base-plate for high power cycling capability AlN substrate for low thermal resistance Improved high reliability package Doc. No. 5SYA555-4Feb 4 Maximum rated values ) Parameter Symbol Conditio min max Unit Collector-emitter voltage VCES VGE = V, Tvj 25 C 7 V DC collector current IC Tc = 8 C 24 A Peak collector current ICM tp = ms, Tc = 8 C 48 A Gate-emitter voltage VGES -2 2 V Total power dissipation Ptot Tc = 25 C, per switch (IGBT) 43 W DC forward current IF 24 A Peak forward current IFRM 48 A Surge current IGBT short circuit SOA IFSM tpsc VR = V, Tvj = 25 C, tp = ms, half-sinewave VCC = 2 V, VCEM CHIP 7 V VGE 5 V, Tvj 25 C 2 A µs Isolation voltage Visol min, f = 5 Hz 4 V Junction temperature Tvj 5 C Junction operating temperature Tvj(op) -5 25 C Case temperature Tc -5 25 C Storage temperature Tstg -5 25 C Mounting torques 2) Ms Base-heatsink, M6 screws 4 6 Mt Main terminals, M8 screws 8 Mt2 Auxiliary terminals, M4 screws 2 3 ) Maximum rated values indicate limits beyond which damage to the device may occur per IEC 6747 2) For detailed mounting itructio refer to ABB Document No. 5SYA239 Nm
5SNA 24E7 IGBT characteristic values 3) Parameter Symbol Conditio min typ max Unit Collector (-emitter) breakdown voltage Collector-emitter 4) saturation voltage V(BR)CES VGE = V, IC = ma, Tvj = 25 C 7 V VCE sat IC = 24 A, VGE = 5 V Collector cut-off current ICES VCE = 7 V, VGE = V Tvj = 25 C 2. 2.3 2.6 V Tvj = 25 C 2.3 2.6 2.9 V Tvj = 25 C 2 ma Tvj = 25 C 2 ma Gate leakage current IGES VCE = V, VGE = 2 V, Tvj = 25 C -5 5 na Gate-emitter threshold voltage VGE(TO) IC = 24 ma, VCE = VGE, Tvj = 25 C 4.5 6.5 V Gate charge Qge IC = 24 A, VCE = 9 V, VGE = -5 V.. 5 V Input capacitance Cies 228 VCE = 25 V, VGE = V, f = MHz, Output capacitance Coes 22. Tvj = 25 C Reverse trafer capacitance Cres 9.6 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 ISC VCC = 9 V, IC = 24 A, RG =.56, VGE = 5 V, L = 6 nh, inductive load VCC = 9 V, IC = 24 A, RG =.56, VGE = 5 V, L = 6 nh, inductive load VCC = 9 V, IC = 24 A, VGE = ±5 V, RG =.56, L = 6 nh, inductive load VCC = 9 V, IC = 24 A, VGE = ±5 V, RG =.56, L = 6 nh, inductive load tpsc μs, VGE = 5 V, Tvj = 25 C, VCC = 2 V, VCEM CHIP 7 V Tvj = 25 C 32 Tvj = 25 C 32 Tvj = 25 C 27 Tvj = 25 C 275 Tvj = 25 C Tvj = 25 C 9 Tvj = 25 C 25 Tvj = 25 C 265 Tvj = 25 C 495 Tvj = 25 C 7 Tvj = 25 C 85 Tvj = 25 C 22 µc nf mj mj A Module stray inductance L CE nh Resistance, terminal-chip RCC +EE 3) Characteristic values according to IEC 6747 9 4) Collector-emitter saturation voltage is given at chip level TC = 25 C.6 TC = 25 C.85 mω Doc. No. 5SYA555-4Feb 4 page 2 of 9
5SNA 24E7 Diode characteristic values 5) Parameter Symbol Conditio min typ max Unit Forward voltage 6) VF IF = 24 A Reverse recovery current Recovered charge Reverse recovery time Reverse recovery energy 5) Characteristic values according to IEC 6747 2 6) Forward voltage is given at chip level Irr Qrr trr Erec VCC = 9 V, IF = 24 A, VGE = 5 V, RG =.56 L = 6 nh inductive load Tvj = 25 C.65 2. Tvj = 25 C.7 2. Tvj = 25 C 52 Tvj = 25 C 88 Tvj = 25 C 59 Tvj = 25 C 25 Tvj = 25 C 58 Tvj = 25 C 87 Tvj = 25 C 42 Tvj = 25 C 72 V A µc mj Thermal properties 7) Parameter Symbol Conditio min typ max Unit IGBT thermal resistance junction to case Diode thermal resistance junction to case Rth(j-c)IGBT.7 K/W Rth(j-c)DIODE.2 K/W IGBT thermal resistance 2) case to heatsink Diode thermal resistance 7) case to heatsink Rth(c-s)IGBT IGBT per switch, grease = W/m x K.9 K/W Rth(c-s)DIODE Diode per switch, grease = W/m x K.8 K/W 2) For detailed mounting itructio refer to ABB Document No. 5SYA239 Mechanical properties 7) Parameter Symbol Conditio min typ max Unit Dimeio L x W x H Typical, see outline drawing 9 x 4 x 38 mm Comparative tracking index CTI 6 Clearance distance in air Surface creepage distance da ds according to IEC 6664- and EN 524- according to IEC 6664- and EN 524- Term. to base: 23 Term. to term: 9 Term. to base: 28.2 Term. to term: 28.2 Mass m 2 g 7) Thermal and mechanical properties according to IEC 6747 5 mm mm Doc. No. 5SYA555-4Feb 4 page 3 of 9
5SNA 24E7 Electrical configuration 3 9 7 5 2 8 6 4 Outline drawing 2) Note: all dimeio are shown in mm 2) For detailed mounting itructio refer to ABB Document No. 5SYA239 This is an electrostatic seitive device, please observe the international standard IEC 6747-, chap. IX. This product has been designed and qualified for Industrial Level. Doc. No. 5SYA555-4Feb 4 page 4 of 9
5SNA 24E7 48 44 48 44 V CE = 25 V 4 36 25 C 25 C 4 36 32 32 28 28 24 24 2 2 6 2 6 2 25 C 8 8 25 C 4 V GE = 5 V 2 3 4 5 4 2 3 4 5 6 7 8 9 2 3 V GE [V] Fig. Typical on-state characteristics, chip level Fig. 2 Typical trafer characteristics, chip level 48 48 44 4 36 32 28 7V 5V 3V V 9V 44 4 36 32 28 7V 5V 3V V 9V 24 24 2 2 6 6 2 2 8 8 4 T vj = 25 C 4 2 3 4 5 6 2 3 4 5 6 Fig. 3 Typical output characteristics, chip level Fig. 4 Typical output characteristics, chip level Doc. No. 5SYA555-4Feb 4 page 5 of 9
5SNA 24E7 3. 2.5 V CC = 9 V R G =.56 ohm V GE = ±5 V L = 6 nh 3. 2.5 V CC = 9 V I C = 24 A V GE = ±5 V L = 6 nh 2. 2. E on Eon, Eoff [J].5 Eon, Eoff [J].5 E off. E off E on..5.5. E sw [mj] =.38 x -4 x I C 2 +.28 x I C + 233 2 3 4 5. 2 3 4 R G [ohm] Fig. 5 Typical switching energies per pulse vs collector current Fig. 6 Typical switching energies per pulse vs gate resistor V CC = 9 V R G =.56 ohm V GE = ±5 V L = 6 nh V CC = 9 V I C = 24 A V GE = ±5 V L = 6 nh td(on), tr, td(off), tf [µs] t d(off) td(on), tr, td(off), tf [µs] t d(off) t r t d(on) t d(on) t f t f. t r. 2 3 4 5 2 3 4 5 R G [ohm] Fig. 7 Typical switching times vs collector current Fig. 8 Typical switching times vs gate resistor Doc. No. 5SYA555-4Feb 4 page 6 of 9
5SNA 24E7 2 V CC = 9 V C ies 5 V CC = 3 V C [nf] C oes VGE [V] C res V GE = V f OSC = MHz V OSC = 5 mv 5 5 2 25 3 35 5 I C = 24 A T vj = 25 C 2 4 6 8 2 4 6 8 2 Q g [µc] Fig. 9 Typical capacitances vs collector-emitter voltage Fig. Typical gate charge characteristics 2.5 V CC 2 V, V GE = ±5 V, R G =.56 ohm 2.5 ICpulse / IC.5 Chip Module 5 5 2 Fig. Turn-off safe operating area (RBSOA) Doc. No. 5SYA555-4Feb 4 page 7 of 9
5SNA 24E7 9 8 V CC = 9 V R G =.56 ohm L = 6 nh 25 2 2 V CC = 9 V I F = 24 A L = 6 nh I rr 24 2 Erec [mj] 7 6 5 4 3 2 I rr Q rr E rec E rec [mj] = -4.53 x -5 x I 2 F +.382 x I F + 76 2 3 4 5 I F [A] 5 5 Irr [A], Qrr [µc] Erec [mj], Qrr [µc] 8 6 4 2 Q rr E rec RG = 3.9 ohm RG = 2.2 ohm RG =.5 ohm RG =. ohm RG =.82 ohm RG =.56 ohm 2 3 4 5 6 7 8 9 di/dt [ka/µs] 6 2 8 4 Irr [A] Fig. 2 Typical reverse recovery characteristics vs forward current Fig. 3 Typical reverse recovery characteristics vs di/dt I F [A] 48 44 4 36 32 28 24 2 6 25 C 25 C IR [A] 52 48 44 4 36 32 28 24 2 6 V CC 2 V di/dt 2 ka/µs 2 2 8 8 4 4.5.5 2 2.5 V F [V] 5 5 2 V R [V] Fig. 4 Typical diode forward characteristics, chip level Fig. 5 Safe operating area diode (SOA) Doc. No. 5SYA555-4Feb 4 page 8 of 9
5SNA 24E7. Analytical function for traient thermal impedance: Zth(j-c) [K/W] IGBT, DIODE.. Z th(j-c) Diode Z th(j-c) IGBT IGBT Z th (j-c) (t) = n i R (- e i 2 3 4 Ri(K/kW) 5.59.2.495.246 i(ms) 22.9 2.3 2..52 i -t/ i ) DIODE Ri(K/kW) 8.432.928.866.839 i(ms) 2 29.6 7..49.... t [s] Fig. 6 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 258 Surge currents for IGBT diodes 5SYA 293 Thermal design of IGBT modules 5SYA 298 Paralleling of IGBT modules 5SZK 9 Specification of environmental class for HiPak Storage 5SZK 92 Specification of environmental class for HiPak Traportation 5SZK 93 Specification of environmental class for HiPak Operation (Industry) 5SZK 92 Specification of environmental class for HiPak 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 coent is forbidden. Any liability for use of our products contrary to the itructio in this document is excluded. ABB Switzerland Ltd Doc. No. 5SYA555-4Feb 4 Semiconductors Fabrikstrasse 3 CH-56 Lenzburg, Switzerland Telephone +4 ()58 586 49 Fax +4 ()58 586 36 Email abbsem@ch.abb.com Internet www.abb.com/semiconductors