Designed for switching regulator, DC-DC converter, AC-DC inverter, high voltage, high speed switching applications. Features: VCEO(sus) = 400V (Min). VcEvV = 700V blocking capability Excellent switching time: ty = 1.5 us (Max.), t = 0.7 us (Max.) NPN POWER TRANSISTORS MJE13007 400 VOLTS 8 AMP, 80 WATTS NPN COLLECTOR BASE EMITTER CASE STYLE TO-220AB DIMENSIONS ARE IN INCHES AND (MILLIMETERS) .116(2.95 -404(10.26) Hees .190(4,83) 5511.39 $8018.68) | \ 70(4.32) {ow be oes 1 ! 0481. TI - . .265(6.73 4 co 5 = e -245(6.22} . CASE ; TEMPERATURE | f sent .355(9.02 145(3.68 + '5(8.25) Faria. 5a) 0A. | \ v | } 2015.59) 0060.15 Fr TE RM.2-~ 988 TERM. [ .130(3.3} il 60710.025) A .500(12.7}MIN. (1.39 4 107(2.72 ,033(0.84) 7051267 027(0.69) else O87(2.21) 5511.39) Eo 210(5.33) 0210.53) x 1.14) -190(4,82} 7510.38) [_Terw2 | Terms [| aa | (tee [Ternw.1 [ coucecron | emitren | coucector | [To-220-aB | BASE maximum ratings (Ta = 25C) (unless otherwise specified) RATING SYMBOL MJE13007 UNITS Collector-Emitter Voltage VcEO 400 Volts Collector-Emitter Voltage VoEV 700 Volts Emitter Base Voitage VEBO 9 Volts Collector Current Continuous lo 8 A Pulse lop 16 Base Current Continuous lp 4 A Pulse Iep 8 Emitter Current Continuous le 12 A Pulse lep 24 Collector Power Dissipation Ta = 25C Po 2 Watts Derate above 25C 16 mw/?C Coilector Power Dissipation To = 25C Po 80 Watts Derate above 26C 640 mWw/C Operating and Storage Junction Temperature Range Ty, TstG -65 to +150 C 729thermal characteristics Thermal Resistance, Junction to Case Resc 1.56 C/W Thermal Resistance, Junction to Ambient Resa 62.5 C/W Maximurn Lead Temperature for Soldering Purpose: % from Case for 5 Seconds Th 275 C electrical characteristics (Tc = 25C) (unless otherwise specified) CHARACTERISTIC | SYMBOL | MIN | TYP MAX UNIT | off characteristics Collector-Emitter Voltage VCEQ(sus) 400 Volts (I = 10mA, Ip = 0) Collector Cutoff Current (VcE = 700V, Vee = -1.5V) ICEV _ _ 1 mA (VCE = 700V, VBE = -1.5V, To = 100C) 5 Emitter Cutoff Current (Vep = 9V, Ic = 0) lEBO _ 1 mA second breakdown Second Breakdown with Base Forward Biased FBSOA SEE FIGURE 1 Clamped Inductive SOA with Base Reversed Bias RBSOA SEE FIGURE 2 on characteristics") DC Current Gain (Ig = 2A, Voce = 5V) Nee 8 _ 60 (I = 5A, VE = 5V) 5 30 Collector-Emitter Saturation Voltage Vi (Ic = 2A, Ip = 0.4A) 9 CE(sat) _ _ V (Io = SA, Ip = 1A) _ _ 2 (Ig = 8A, Ip = 2A) _ 3 (Ig = 5A, Ip = 1A, To = 100C) = = 3 Base-Emitter Saturation Voltage VBE(sat) (Ig = 2A, Ip = 0.4A) 1.2 Vv (Ic = SA, Ip = 1A) _ ~ 1.6 (Ig = 5A, Ip = 1A, Tc = 100C) 1.5 dynamic characteristics Output Capacitance _ _ (Vop = 10V, Ie = 0, f= 0.1 MHz) Cob 90 pF Current Gain - Bandwidth Product (Ig = 500MA, Vor = 10V, frest = 1.0 MHz) fr 4 MHz switching characteristics Resistive Load Delay Time (Voc = 125V, Io = 2A ta _ _ 0.1 BS Rise Time Ig1 = -Ipo = 0.4A, tp = 25 us tr _ _ 1.5 Storage Time Duty Cycle < 1%) ts _ 3 Fall Time tt _ _ 0.7 Inductive Load, Clamped v7 Inductive Load (Ic = 5A, _ _ Storage Time Velamp = 300V, Igi = 1A, tsy 2.3 us Crossover Time VBE(off) = -5V, Tc = 100C) te 0.7 (1) Pulse Test: Pulse Width - 300us Duty Cycle :< 2%. 730POWER DERATING FACTOR hee, DC CURRENT GAIN ic, COLLECTOR CURRENT (AMP) 20 FIGURE 1 FORWARD BIAS SAFE OPERATING AREA oo = 26C Ic, COLLECTOR (AMP) =~ THERMAL LIMIT ~- BONDING WIRE LIMIT SECOND BREAKOOWN CURVES APPLY BELOW RATED V MJE13007 10 50 70 1 200 Vce, COLLECTOR EMITTER VOLTAGE (VOLTS) 7 500 To < 100C 1g1=2.5A VeE(ott) = 9V MJE1 100 200 300 400 500 600 700 VcEV, COLLECTOR-EMITTER CLAMP VOLTAGE (VOLTS) 800 FIGURE 2 REVERSE BIAS SWITCHING SAFE OPERATING AREA The Safe Operating Area figures shown in Figures 1 and 2 are specified ratings for these devices under the test conditions shown. ECONO BREAKO DERATIN ERATING TRANSIENT THERMAL RESISTANCE (NORMALIZED) 60 80 100 120 140 160 Tr, CASE TEMPERATURE (C) 40 FIGURE 3 FORWARD BIAS POWER DERATING 0.1 Vee, COLLECTOR-EMITTER VOLTAGE (VOLTS) 0.2 0.3 05 07 #1 2 3 Ic, COLLECTOR CURRENT (AMP) FIGURE & DC CURRENT GAIN 731 O7 05 Og 0.2 0.1 0.07 0.05 9.01 0.01 0.02 0.05 0.1 ops 0.07 0.1 Zeaucit) = r(t) Rey Rasc = 1.96C/W MAX 0 CURVES APPLY FOR POWER PULSE TRAIN SHOWN READ TIME @ty Toipk) - TS = Pipk) Zauctty DUTY CYCLE, D= ty/t2 _s = JU Ly LL P(pk) '2 20 50 100 200 500 10k SINGLE PULSE 02 #05 #10 20 .0 10 TIME (ms) FIGURE 4 TYPICAL THERMAL RESPONSE [(Zgyc(t)] 02 03 O08 OF 1 Ig, BASE CURRENT (AMP) FIGURE 6 COLLECTOR SATURATION REGION0.3 0.5 1 3 10 1c, COLLECTOR CURRENT {AMP) FIGURE 8 COLLECTOR-EMITTER SATURATION VOLTAGE 1 00. 1000 VR, REVERSE VOLTAGE (VOLTS) FIGURE 10 CAPACITANCE Vcc = 125V Ic/tg =5 Ty = 26C 1.8 0.7 1.6 0.6 B14 a 05 3 3 2 12 > 04 ws ua 2 2 5 1 5 $ $ > 08 > 02 0.1 oT 2 03S ON 0 {07 Ic, COLLECTOR CURRENT (AMP} FIGURE 7? BASE-EMITTER SATURATION VOLTAGE 10K 10K Vce = 250 V 5K 1K < 2K > Ty = 150C = 1k a 100 125 ws = 2 500 > 1 < e 5 < a 5 ad 10; - z 0C a 50 ow 4 Oo - 25C 01 REVERSE FORWARD -0.4 -02 0 +0.2 +04 Vpe. BASE-EMITTER*VOLTAGE (VOLTS) FIGURE 9 COLLECTOR CUTOFF REGION RESISTIVE SWITCHING PERFORMANCE Vee = 125V 700 Ic/lg =5 Ty = 2596 3 300 2 2 is $00 ua = = 200 = be ~~ - 300 tg @ VBE(off) = SV 0.5 0. 10 Ic, COLLECTOR CURRENT (AMP) FIGURE 11 TURN-ON TIME 02 03 732 IC, COLLECTOR CURRENT (AMP) FIGURE 12 TURN-OFF TIMEVelamp 90% VCEM 90% Icom {fi Mu TIME FIGURE 13 INDUCTIVE SWITCHING MEASUREMENTS 733 Vv > cE Q 2 < 8 oO > o - rs] a 2 fi] u < at 2 C U0 > Io Vce , 3 TIME 20 ns/Div FIGURE 14 - TYPICAL INDUCTIVE SWITCHING WAVEFORMS (at 300 V and 8A with Igy = 1.6A and Vg_E (off) = 5 V)