TIP125, 126, PNP POWER DARLINGTON |1TP127 -60 - -100 VOLTS TRANSISTORS Sir 05 WATTS COMPLEMENTARY T0 THE TIP120, TIP121, TIP122 High power switching applications, designed for hammer drive, pulse motor drive and inductive load drive applications. Features: High collector power dissipation: Pp = 65W @ Tc = 25C : E STYLE TO-220AB High collector current: IC(DC) = -5A (Max.) OMe ane IN INCHES AND (MILLIMETERS) e High DC current gain: Sine Tea gets hee = 1000 (Min.) @ VCE = -3V, IC = -3A [ 7 abn) E e Complementary to TIP120, TIP121, TIP122 f aria i: rewhirune 145(3.68) seston nm aa. EgpDlA. | 325(B.25) 22015 0 : 1303.3) >| pe 29510 18) EQUIVALENT CIRCUIT FF . TERM. A 4 .800(12.7)MIN. COLLECTOR TERM2 -066(1.39 TERM.3 ABN. | [wee [termi | TeRM.2 | TERMS | TAB | [ro-220-aa | pase | couvecton | emitTeR | COLLECTOR | EMITTER maximum ratings (T, = 25C) (unless otherwise specified) RATING SYMBOL TIP125 TIP126 TIP127 UNITS Collector-Emitter Voltage VcEO -60 -80 -100 Volts Collector-Base Voltage VcBo -60 -80 -100 Volts Emitter Base Voltage VEBO -5 -5 -5 Volts Coilector Current - Continuous Ic -5 5 -5 A Peak Icom -8 -8 -8 Base Current Continuous IB -0.1 -0.1 -0.1 A Total Power Dissipation @ Ta = 25C Pp 2 2 2 Watts @ Tc = 25C 65 65 65 Operating and Storage Junction Temperature Range Ty, Tsta@ -65 to +150 -65 to +150 -65 to +150 C thermal characteristics Thermal Resistance, Junction to Ambient Resa 62.5 62.5 62.5 C/W Thermal Resistance, Junction to Case Rguc 1.92 1.92 1.92 C/W Maximum Lead Temperature for Soldering Purpose: %" from Case for 5 Seconds Th 260 260 260 C 765electrical characteristics (Tc = 25C) (unless otherwise specified) | CHARACTERISTIC | SYMBOL| MIN | TYP | MAX | UNIT | off characteristics Collector-Emitter Breakdown Voltage TIP125 | Vericeo -60 _ Volts (Ig = -30mA) 9 TIP126 (CEO) | 780 _ TIP127 - =100 Collector Cutoff Current (VcB = -80V) IcBo _ _ -200 pA Collector Cutoff Current Emitter Cutoff Current (Vep = -5V) |EBO ~ _ 2 mA second breakdown | Second Breakdown with Base Forward Biased | FBSOA SEE FIGURE 13 on characteristics DC Current Gain hre (Io = -0.5A, Veg = -3V) 1000 _ _ _ (Ig = -3A, Vcg = -3V) 1000 = _ Collector-Emitter Saturation Voltage VCE(sat) (Ic = -3A, Ig = -12mA) -2 Vv (Ic = -5A, Ig = -20mA) -4 Vv Base-Emitter Voltage VBE (Ig = -3A, Voge = -3V) (on) _ 2.5 V switching characteristics Turn-on Time Ig = -3A, Ry = 100 ton 1.5 us - Ig1 = -lp2=-12mA Turn-off Time VBE(ott) = 5V tott 8.5 _ COMMON EMITTER Tg = 25C COLLECTOR CURRENT Ig (A} 0 2 4 6 48 -10 12 COLLECTOR-EMITTER VOLTAGE Veg (V) FIG.1 Ic-VcE 766 COLLECTOR CURRENT Ic (A) 2 4 6 COMMON EMITTER To= 100C 48 10 COLLECTOR-EMITTER VOLTAGE Voce (V} FIG. 2 lo - VCE: 12COLLECTOR CURRENT Ic (A) COLLECTOR-EMITTER SATURATION VOLTAGE Voe,saty ) COLLECTOR CURRENT Ic (A) 10,000 COMMON EMITTER: COMMON EMITTER To = 55C Voge = 3V 5,000 5.0 3,000 fv x z $ 1,000 Ee 6 5 600 8 300 0 2 of 6 8 -10 42 214 100 0.1 03 4 3 -10 COLLECTOR-EMITTER VOLTAGE Vee (V) FIG.3 Ic-VCE oe ee lc COMMON EMITTER Io/lig = 250 COMMON EMITTER lo/Ig = 250 To = 85C 25 BASE-EMITTER SATURATION VOLTAGE VeE(saty (V) 100 0.4 03 4 3 -10 0. 03 4 3 10 COLLECTOR CURRENT i (A) COLLECTOR CURRENT Ic (A) FIG.5 VcE(eat) -!c FIG.6 VBE(sat) - Ic COMMON EMITTER COMMON EMITTER Voe = -3V COLLECTOR-EMITTER SATURATION VOLTAGE Voetsaty (V) -80 -40 40 80 120 160 200 o -0.4 08 +12 1.6 20 2.4 -2.8 CASE TEMPERATURE Tc (C) BASE-EMITTER VOLTAGE Vp (V) FIG.8 VCE(sat) - Te FIG.7 lic-VeE 767BASE-EMITTER VOLTAGE Vp. (V} MAXIMUM CONTINUOUS COLLECTOR POWER DISSIPATION Po (W) -80 COMMON EMITTER Voe = -3V 0 40 80 120 CASE TEMPERATURE Te (C) FIG.9 VBE - Te MAXMUM CONTINUOUS COLLECTOR POWER DISSIPATION Pc (W) Rtn(j-a) S6.25CAN 40 60 80 100 120 AMBIENT (FREE-AIR) TEMPERATURE Ta (C) FIG.12 PcTa 20 140 40 160 MAXIMUM COLLECTOR CURRENT Ic (A) Vo = -20V Aga = 1009 Te = 26C SEE FIGURE 2 1 3 10 30 100 UNCLAMPED INDUCTIVE LOAD L (mH) FIG. 10 i - L (UNCLAMPED INDUCTIVE LOAD) Rih(-c) = 192C/w 60 80 100 120 140 160 CASE TEMPERATURE Tc (C) Pc-Te FIG. 11 768 COLLECTOR CURRENT Ic (A) ~20 ~10 Ic MAX. (PULSED) Ig MAX. (CONTINUOUS) -5 -3 3 3 3% oF" 1 SINGLE NONREPETITIVE PULSE Te = 26C CURVES MUST BE DERATED LINEARLY WITH INCREASE IN TEMPERATURE. -0.4 -1 3 ~10 -30 -100 COLLECTOR-EMITTER VOLTAGE Voe (V) FIG. 13 SAFE OPERATING AREA\g MONITOR Tut Voe ; proc ctccom MONITOR KJ ie j ( 4 any poe Agar ' t 8 10% f 90% las Vy O Ww rr \ is (PULSE) ' ~ t ton tott 3 =_vyv" AMA gS ; Ae A s 10% " Lio He 4 a \ VcE 90% Vea Voc = -30V ce {A) The VIN waveform is obtained by using amplifier circuit and the signal source is supplied by generator with the following characteristics: ty, ty < 15ns, ty, = 204s, Du = 1% (8) -Ving Regs 4nd Raga are varied to obtain desired base current levels. FIG. 14. SWITCHING TIME MEASUREMENT CIRCUIT Tur poco e ee meee 1 poenenamene () t Ic. Voe Feat ' 1 MONITOR Ic Vy oO. AWA . (PULSE) \ aK, | 1A g) | ! y & l CE(sat) x ! WV I L= 100 mH SF f -2ov L-i----- J Vi L = 100mH CE V, Vo = -20 CER(SUS) (INPUT PULSE WIDTH iS INCREASED UNTIL Icp = -1A. FIG.15 INDUCTIVE LOAD SWITCHING TEST 769