STGW20NB60H N-CHANNEL 20A - 600V TO-247 PowerMESH IGBT T YPE STGW 20NB60H ■ ■ ■ ■ ■ ■ V CES V CE(sat) IC 600 V < 2.8 V 20 A HIGH INPUT IMPEDANCE (VOLTAGE DRIVEN) LOW ON-VOLTAGE DROP (VCESAT) LOW GATE CHARGE HIGH CURRENT CAPABILITY VERY HIGH FREQUENCY OPERATION OFF LOSSES INCLUDE TAIL CURRENT 1 DESCRIPTION Using the latest high voltage technology based on a patented strip layout, STMicroelectronics has designed an advanced family of IGBTs, the PowerMESH IGBTs, with outstanding perfomances. The suffix ”H” identifies a family optimized to achieve very low switching times for high frequency applications (<120kHz). 2 3 TO-247 INTERNAL SCHEMATIC DIAGRAM APPLICATIONS ■ HIGH FREQUENCY MOTOR CONTROLS ■ WELDING EQUIPMENTS ■ SMPS AND PFC IN BOTH HARD SWITCH AND RESONANT TOPOLOGIES ABSOLUTE MAXIMUM RATINGS Symbol Value Unit V CES Collector-Emitter Voltage (VGS = 0) Parameter 600 V V ECR Emitter-Collector Voltage 20 V V GE G ate-Emitter Voltage ± 20 V o IC Collector Current (continuous) at Tc = 25 C 40 A IC Collector Current (continuous) at Tc = 100 C o 20 A Collector Current (pulsed) 160 A T otal Dissipation at Tc = 25 C 150 W Derating Factor 1.2 W /o C I CM (•) P tot T s tg Tj o Storage T emperature Max. Operating Junction Temperature -65 to 150 o C 150 o C (•) Pulse width limited by safe operating area June 1999 1/8 STGW20NB60H THERMAL DATA R thj -case R thj -amb R thc-h Thermal Resistance Junction-case Thermal Resistance Junction-ambient Thermal Resistance Case-heatsink Max Max Typ o 0.83 30 0.1 C/W oC/W o C/W ELECTRICAL CHARACTERISTICS (Tj = 25 oC unless otherwise specified) OFF Symbol Parameter Test Conditions Collector-Emitt er Breakdown Voltage I C = 250 µA I CES Collector cut-off (V GE = 0) V CE = Max Rating V CE = Max Rating IGES Gate-Emitter Leakage Current (VCE = 0) V GE = ± 20 V V BR(CES) Min. V GE = 0 Typ. Max. 600 Unit V 10 100 µA µA ± 100 nA Max. Unit 5 V 2.3 1.9 2.8 V V Min. Typ. Max. Unit 7.0 10 1200 140 28 1700 200 40 2200 260 52 pF pF pF 110 13 51 145 nC nC nC T j = 25 oC T j = 125 o C V CE = 0 ON (∗) Symbol V GE(th) V CE(SAT ) Parameter Test Conditions Gate Threshold Voltage V CE = V GE IC = 250 µA Collector-Emitt er Saturation Voltage V GE = 15 V V GE = 15 V IC = 20 A IC = 20 A Min. Typ. 3 Tj = 125 oC DYNAMIC Symbol gf s Parameter Test Conditions Forward Transconductance V CE =25 V C i es C o es C res Input Capacitance Output Capacitance Reverse Transfer Capacitance V CE = 25 V QG Q GE Q GC Total G ate Charge Gate-Emitter Charge Gate-Collector Charge V CE = 480 V Latching Current V clamp = 480 V T j = 150 o C I CL I C = 20 A f = 1 MHz IC = 20 A V GE = 0 VGE = 15 V R G =10 Ω S 80 A SWITCHING ON Symbol t d(on) tr (di/dt) on Eo n 2/8 Parameter Test Conditions Min. Typ. Max. Unit Delay Time Rise Time V CC = 480 V V GE = 15 V I C = 20 A R G = 10Ω 20 70 ns ns Turn-on Current Slope V CC = 480 V R G = 10 Ω T j = 125 o C I C = 20 A V GE = 15 V 350 A/µs 300 µJ Turn-on Switching Losses STGW20NB60H ELECTRICAL CHARACTERISTICS (continued) SWITCHING OFF Symbol Parameter Test Conditions Min. Typ. Max. Unit tc t r (v off ) td (o ff ) tf E o ff(**) E ts Cross-O ver Time V CC = 480 V Off Voltage Rise Time R GE = 10 Ω Delay Time Fall T ime Turn-off Switching Loss Total Switching Loss I C = 20 A V GE = 15 V 115 32 170 75 0.4 0.65 ns ns ns ns mJ mJ tc t r (v off ) td (o ff ) tf E o ff(**) E ts Cross-O ver Time VCC = 480 V Off Voltage Rise Time R GE = 10 Ω T j = 125 o C Delay Time Fall T ime Turn-off Switching Loss Total Switching Loss I C = 20 A V GE = 15 V 190 55 210 140 0.7 1.0 ns ns ns ns mJ mJ (•) Pulse width limited by max. junction temperature (∗) Pulsed: Pulse duration = 300 µs, duty cycle 1.5 % (**)Losses Include Also The Tail (Jedec Standardization) Thermal Impedance 3/8 STGW20NB60H Output Characteristics Transfer Characteristics Transconductance Collector-Emitter On Voltage vs Temperature Collector-Emitter On Voltage vs Collector Current Gate Threshold vs Temperature 4/8 STGW20NB60H Normalized Breakdown Voltage vs Temperature Capacitance Variations Gate Charge vs Gate-Emitter Voltage Total Switching Losses vs Gate Resistance Total Switching Losses vs Temperature Total Switching Losses vs Collector Current 5/8 STGW20NB60H Switching Off Safe Operating Area Fig. 1: Gate Charge test Circuit Fig. 3: Switching Waveforms 6/8 Fig. 2: Test Circuit For Inductive Load Switching STGW20NB60H TO-247 MECHANICAL DATA mm DIM. MIN. TYP. inch MAX. MIN. TYP. MAX. A 4.7 5.3 0.185 0.209 D 2.2 2.6 0.087 0.102 E 0.4 0.8 0.016 0.031 F 1 1.4 0.039 0.055 F3 2 2.4 0.079 0.094 F4 3 3.4 0.118 0.134 G 10.9 0.429 H 15.3 15.9 0.602 0.626 L 19.7 20.3 0.776 0.779 L3 14.2 14.8 0.559 0.582 L4 34.6 1.362 L5 5.5 0.217 M 2 3 0.079 0.118 P025P 7/8 STGW20NB60H Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibil ity for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specific ation mentioned in this publication are subjec t to change without notice. This publication supersedes and replaces all information previously supplied. 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