Data Sheet No. PD-2.030D INTERNATIONAL RECTIFIER | T4R 1I1N3879, INS&BSSY, GFL, 12FL, 16FL SERIES GA, 12A and 1GA Fast Recovery Rectifiers Major Ratings and Characteristics Description j 13879 | 1N3B8O This range of fast recovery diodes is _=1Nap83 1NaBG3 | OFL.. | 12FL. vot.. Unit designed for applications in OC power i > > f supplies, inverters, converters, choppers, teaavy? | 6 12 6 2) 16 A a , , a a + ultrasonic systems and for use as free Veg@ et} 145 | io | 145 | 180 | A wheel diodes. 60Hz 75 150* i; 115 150 190 A 7 Features 2 SOHz 26 103 6Q | 103 160 As 6oHz |! 23 94 55 | 94 | isq | As W Short reverse recovery time AT 363 1452 ass | 1452 | 2200 | AAs Wl Low stored charge t,, range see table ns Mi Wide current range Vegan "nge| 50 400 : 50 1000 v @ Excellent surge capabilities T, range 65 to 150 a Standard JEDEC types ! . *JEDEC registered values. Wi Stud cathode and stud anode versions + At max. Te = 100C, Mi Types up to 1000V Very @ Fully characterised reverse recovery conditions CASE STYLE AND DIMENSIONS te < = 2 3 S a 2 10.45) 10.74} = Conforms to JEDEC : DO~209AA (DO4) 11.00 (0.433) MAX. \EC 191-2: A3U ACROSS FLATS . } 2 8S 3934: SO-10A DIN 41885: 10102 Ali dimensions in millimetres (inches)1N3879, 1N3889, GFL, 12FL, 16FL Series REVERSE VOLTAGE RATINGS INTERNATIONAL RECTIFIER Max. reverse re- covery time AM(REC) re- Max. reverse re- covered charge 150 1N3889 150 rom.s. forward current n repetitive forward current Max. 12t for fusing Max. Max. for individual t for individual *JEDEC ragistered value * Suffix S02" may be omitted, i.g., 12FL10 implies 12FL10S02, 12FLAGO implies 12F LAGOSO2. Vram Max. IR Max. Reverse Current Vream Max. Non-Renetitive Feak At Rated VR Repetitive Paak Reverse Voltage Reverse Voltage tp SH ms Ty= 25C | Ty= 100C | Ty = 160C Part Number Oo v v mA ma mA 1N3879 50 76 0.0157 1.0% 3.07 1N3880 100 160 0.015" 1.0* 3.0* 1N3881 200 250 O.0T5* 1.0* 30* Q@) 1N3882 300 350 O.015* 1.0* 3.0r IN3883 400 450. 0.015" 1.0* 3.0* _ 1N3889. 50 aS 0.025" 3.0 5.0 1N3890 100 150 0.025* 3.0* 5.0* -~ 1N3891 200 250 0.025* 3.0" so7 W 1N3892 300 350 0.025* 3.0* 5.0* 1N3893 400 450 0.025* 3.0% 5.0* "6FLESO2 6FL5S05 6FLSSIO 5a 0. = oo 6FL10S02 6FL10S05 6FLIOS10 100 450 0.050 - 60 6FL20S02 6FL20S05 GFL20510 200 276 0.050 - ao SFL40S02 6FL40S0S GFL40S10 400 saa 0,050 - 60 @ 6FLE60S02 6F L60S05 SFL60S10 600 725 0.050 - 60 - 6FL80S05 BFLBOS1O 800 950 0.050 - 60 = E 400519 1000 1250 9.050) 6.0 *12FLSSO2 12FL6S0S 12FL5S10 50 78 0.050 = 6.0 12FL10S02 12FL10805 12FL10510 100 150 0.050 - 6.0 12FL20S02 12FL20505 12FL20S10 200 275 0.050 - 60 _. 1ZFLA0SO2 12F L40S05 12FL40S10 400 500 0.050 - 60 Wt 12FL60SO2 12FL60S05 12FL60S10 600 725 0.050 - 6.0 - 12FL80S05 12FL80S10 800 950 0.050 - 60 = 412FL100505 12FL100S10 1000 1250 0.050 = 6.0 *"1GFL5S02 16FLSS05 16FLSS10 50 75 0.050 = 6.0 16FL10S02 16FL10S05 16FL10S10 100 150 0.050 _ 6.0 16FL20S02 16FL20805 16FL20810 200 275 0.050 - 6.0 16F L40S02 16F L40S05 16FL40S10 400 500 0.050 6.0 16F L60S02 16FL60S05 16F L60S10 600 725 0.050 6.0 - IGF L80S05 I6FLEOSTO 800 350 0.050 - 6.0 = 16FL100S05 16FL100519. 19000 1250 0.050 6.0 REVERSE RECOVERY CHARACTERISTICS 490/100] 250) 430 E = 100 Ajus F/dt = 230 | 4700 | S000 |200 | 1300 150 {1100} 3000 die) = 100 Alas 200 | 1209 | 5000 | 200 | 1200 |5000/ 200 |1200| 5000 1N3893 858 1452 @)Types listed are cathode to case; for anode-to-casa include 'R in code, i.e., 1IN3879R, 6FLR20510, 16FLR40802, Fidt = =x rated lp(a With rated VRRM | sinusoidal half wave, initial Ty ~ 150C Varm = 9 ; With rated VARM A2s Initial Ty = 150C VRAM = 9 2290 (12 = 0.1 ta 10.ms Vv = =mKx IR(AY) @ rated 1E(Ay) end VAM, and Tc = IgM @ rated VARM and Ty = 150C. (2t for time tt, = 2y't Vx When these devices ara ordered without a suffix, 6.g., 40HFL, the ordar will be filled with devices that meet the SOQ2 specification.INTERNATIONAL RECTIFIER Thermal and mechanical specifications 1N3879, 1N3889, GFL, 12FL, 16FL Series 1N3879 1N3889 1N3883 1N3893 6FL... 12FL... IGFL...) Units | Conditions ty Junction operating temperature range 65 to 150 C Tstg Storage temperature range 65 to 175 c Penge Maximum internal thermai resistance, 25 | 2.0 16 | deg CAV | DC operation junction to case i ( Rencs Maximum thermal resistance, case to : Os , deg CAV | Mounting surface flat, smooth and | heatsink greased. ' T Mounting torque to nut 10.6 i Ibfin | Lubricated threads .10% 0.12 kgm (Non-lubricated threads) 12 1 Nm: to device 41.5 (13.5] Ibf.in . 0.13 (0.155) kgf.m 1.3 11.35) Nm wt Approximate weight 7 9 0.25 az Case style GO203AA (DC4) JEDEC e e 1160 , 160 Fs & 5180 5 150 = < Pog @ 140 a 2 = 130 = 130 w 120 yw 120 a @ O10 2410 wy ny Z FI < 400 $ 100 90 goe~ /\ 3 90 1 LS mM = 0 TA Z sof (1207 z 0 FL z 8 eo? SS. = 70 = 70 x x = 60 $ 60 1 2 3 4 S$ 6 7 8 2 10 4 6 8 10 12 AVERAGE FORWARD CURRENT A AVERAGE FORWARD CURRENT A Fig. 1 Average Forward Current Vs. Maximum Fig. 2 Average Forward Current Vs. Maximum Allowable Case Temperature, Allowable Case Temperature, 1N3879 and GFL Series 1N3889 and 12FL Series ? 4 tr 150 2 140 IF c & 130 = ; a i ws 120 4 110 $ IRMRECI a @ 100 IRMIREC) === ORR = 90 te, lem = Peak forward current orior to commutation 6 a dIF/q, 7 Rate of fall of forward current $ 50 leM(REC}= Peak reverse recovery current = 70 tre = Reverse recovery time % 60 QrA = Reverse recovered charge = 3a AVERAGE FORWARD CURRENT A Fig. 3 Average Forward Current Vs. Maximum Allowable Case Temperature, 16FL Series Fig. 4 Reverse Recovery Time Test Waveform1N3879, 1N3889, GFL, 1ZFL, 16FL Series z j 10 8 1N38791N3883 a QE GFL... o Tene. @ = 180 c Ty = 150% 120 2 3 60? 2 30 6 7 = i = 6 isa i ao 5 io - 5 RMS himit - my og 4 < G3 > = 2 2 : 2 : = 1 - I Conduction z 0 . Angle = o 1 2 3 4 5 AVERAGE FORWAAD CURRENT-A INTERNATIONAL RECTIFIER Ss | o/|z gig = 8 oy ei< = fol oO : i : 6 10 20 30 40 60 60 70 80 90 100 MAXIMUM ALLOWABLE AMBIENT TEMPERATURE C Fig. 5 Current Rating Nomogram (Sinusoidal Waveforms), 1N3879 and GFL Series 1N98791N3BB2 wb BFL. Ty = 150C | | @= 180 60 8 30 i ! | 1 10 : 420 ' i MAXIMUM AVERAGE FORWARD POWER LOSS - W AVERAGE FORWARD CURRENT - A RMS fimit | - 4 @ 2 Conduction Angle o oj o% 2 344 5 B68 7F 8 @ | a| 2 a1 x e: 2 1 ze wi ej < oO 1 1 pe} o PO heatsiny i 30 [220 10170 20 30 40 50 60 70 80 90 100 MAXIMUM ALLOWABLE AMBIENT TEMPERATURE C Fig. 6 Current Rating Nomogram (Rectangular Waveforms), 1N3879 and GFL Series 1N3889--1N3893 18 fF 12FL.. z Ty= 150C | 4999 60 30 16 14 42 FMS limit .- 4 @ 2 Conduction MAX{MUM AVERAGE FORWARD POWER LOSS - W 234 5 6 7 AVERAGE FORWARD CURRENT A oj1 8 9 10 11 KW AR Conduction angie a | 12, 10 20 30 49 50 60 70 80 9G 100 MAXIMUM ALLOWABLE AM&{ENT TEMPERATURE C Fig. 7 Current Rating Nomogram (Sinusoidal Waveforms), 1N3889 and 12FL Series1N3879, 1N3889, 6FL, 12FL, 16FL Series 30 : 1N38891N3893 | 12FL... 25 LT, = 150C toto @ = 180 120 60 30 20 g Conduction | Angle 0 MAXIMUM AVERAGE FORWARD POWER LOSS W a Qo 2.4 6 8 10 12 14 16 AVERAGE FORWARD CURRENT A 18 20 INTERNATIONAL RECTIFIER SR KIW Conduction angle @ o oO o 180] 0.26 120] 0-46 60 | 1.02 30 | 1-76 nO heatsink 10 20 30 40 50 60 70 #80 30 1U0 MAXIMUM ALLOWABLE AMBIENT TEMPERATURE ~ C Fig. 8 Current Rating Nomogram (Rectangular Waveforms}, 1N3889 and 12FL Series Ty = 150C = 180 120 60 30 Conduction Angie 9 2 4 6 8 10 12 14 AVERAGE FORWARD CURRENT A MAXIMUM AVERAGE FORWARD POWER LOSS W Kw ys AR Conduction angle @ i. SP Ss * fy a 3 } 0-37 n a 0-39 QD a a 0-82 30 | 1-44 16 #10 20 30 40 50 60 70 80 90 100 MAXIMUM ALLOWABLE AMBIENT TEMPERATURE C Fig. 9 Current Rating Nomogram (Sinuscidal Waveforms), 16FL Series 35 GFL... 30 Lut 1s0Pe o- 180 25 420 60 30 20 15 F RMS limit 10 @ Conduction Angle MAXIMUM AVERAGE FORWARD POWER LOSS W a 5 10 15 20 AVERAGE FORWARD CURRENT A Kiw Conduction angle @ SR Qo oO ~4R 180} 0-21 120} 0-37 to. a Ar 0-82 60? t \ 30 | 1-41 25 #10 20 30 40 50 60 70 80 90 100 MAXIMUM ALLOWABLE AMBIENT TEMPERATURE C Fig. 10 Current Rating Nomogram (Rectangular Waveforms}, 16F L Series1N3879, 1N3889, GFL, 12FL, 16FL Series INTERNATIONAL RECTIFIER oO a 1N38791N3883 GFL... 1N38791N3883 BFL. mo @ = 180 10? INSTANTANEOUS FORWARD CURRENT - A MAXIMUM AVERAGE FORWARD POWER LOSS W Ty= 150C ' : 0 06 10 15 20 25 30 35 40 1 10 1 10 INSTANTANEOUS FORWARD VOLTAGE AVERAGE FORWARD CURRENT 4 Fig. 11 Maximum Forward Voltage Vs. Forward Fig. 12 ~ Maximum High Level Forward Power Loss Current, 1N3879 and 6FL Series Vs. Average Forward Current, 1N3879 and 6FL Series cy 3 G 1N38891N3893 T2FL.., 3 wy o y ] INSTANTANEOUS FORWARD CURRENT A 3 = 2, Ty= 1s0"C MAXIMUM AVERAGE FORWARD POWER LOSS -- w 0 O05 10 15 20 25 30 36 40 1 10 0 INSTANTANEQUS FORWARD VOLTAGE V AVERAGE FORWARD CURRENT A Fig. 13 - Maximum Forward Voltage Vs. Forward Fig. 14 Maximum High Level Forward Power Loss Current, 1N3889 and 12FL Series Vs. Average Forward Current, 1N3889 and 12FL Series my 5 tw Q yD Ty = 150C INSTANTANEOUS FORWARD CURRENT A 1 MAXIMUM AVERAGE FORWARD POWER Loss W 0 05 10 15 20 25 30 38 40 1 107 10 INSTANTANEOUS FORWARD VOLTAGE V AVERAGE FORWARD CURRENT A Fig. 15 Maximum Forward Voltage Vs. Fig. 16 Maximum High Level Forward Power Loss Forward Current, 16FL Series Vs, Average Forward Current, 16FL SeriesREVERSE RECOVERY TIME os REVERSE RECOVERY TIME ns REVERSE RECOVERY TIME ns NTERNATIONAL RECTIFIER Ip = 7x rated le(ay) 800 400 300 20 6FL...S02 12FL...S02 16FL,..SO2 410 1 3 10 30 400 RATE OF FALL OF FORWARD CURRENT A/us Fig. 17A Maximum Reverse Recovery Time Vs. Rate of Fall of Forward Current, All Series __S02 6FL....505 12FL....S05 16FL....505 3000 Ta7 Ip = 7x rated | Vv) 1000 600 500 400 200 1 (pata 1 3 10 30 100 RATE OF FALL OF FORWARD CURRENT Ajus Fig. 18A Maximum Reverse Recovery Time Vs. Rate of Fall of Forward Current, Ail Series __ 505 6000 5000 4000 3000 1000 600 500 400 300 200 6FL...810 12FL...810 16FL...510 100 1 a 10 30 100 RATE OF FALL OF FORWARD CURRENT A/us Fig. 19A Maximum Reverse Recovery Time Vs. Rate of Fall of Forward Current, All Series __$10 1N3879, 1N3889, GFL, 12FL, 16FL Series 6FL...S02 12ZFL...S02 IGF L...502 ipa 'FLAV} RECOVERED CHARGE nc 1 3 1 RATE OF FALL OF FORWARD CURRENT A/us Fig. 178 Maximum Recovered Charge Vs. Rate of Fali of Forward Current, All Series __ S02 6FL...S05 12FL...S05 16FL...S05 lol Ip = 7x rated lecay) of 8 5 RECOVERED CHARGE ~ nC 1 3 10 30 100 RATE OF FALL OF FORWARD CURRENT A/us Fig. 188 Maximum Recovered Charge Vs. Rate of Fall of Forward Current, All Series ___SO5 10 Ip = 1x rated leyay) eG Se, RECOVERED CHARGE nC I6FL...S10 10 1 3 10 30. 100 RATE OF FALL OF FORWARD CURRENT A/us Fig. 198 Maximum Recovered Charge Vs. Rate of Fall of Forward Current, All Series __S101N3879, 1N3889, 6FL, 1ZFL, 16FL Series INTERNATIONAL RECTIFIER ANY CONGITION AND RATED APPLIED *OLLOWING SUAGE, RATEO LAD CONDITION AND RATED Vag APPLIED FOLLOWING SURGE. PEAK HA! F SINE WAVE FX RWARD CURAFNT (AMPERES) 2 PEAK HALF SINE WAVE FORWARD CURRENT (AMPERES) 2 4 6 40 6a 1 2 4 6 @ 10 20 40 60 NUMBER OF EQUAL AMPLITUDE HALF CYCLE CURRENT PLILSES IN} NUMBER OF EQUAL AMPLITUDE HALF CYCLE CURRENT PILSES (Nn) Fig, 20 -- Maximum Non- Repetitive Surge Current Fig. 21 Maximum Non-Repetitive Surge Current Vs. Number of Current Pulses, 1N3879 Series Vs. Number of Current Pulses, GFL Series AT ANY 4oaD RATED Vaam APPLIED FOL LOW-NG SL RGE. AND RATED APPLIED FOLLIWING SURGE. PEAK HALF SINE WAYE FORWARD CURRENT (AMPERES) PEAK HALF SINE WAVE FORWARD CURRENT LAMPE RES) 4 NUMBER OF EQUAL AMPLITUUE HALF CYCLE CURRENT PULSES (NI NUMBER DF EQUAL AMPLITUDE HALF CYCLE CURRENT PULSES (N) Fig. 22 Maximum Non-Repetitive Surge Current Fig. 23 Maximum Non-Rapetitive Surge Current Vs. Number of Current Pulses, Vs. Number of Current Pulses, 16FL Series IN3889 and 12FL Series 10 1N38791N2B82 w BFL... z a2 vo 22 at <<. =3 cs 1 ie re 65 ae a2 g32 ft ec Fe 104 19 10 1 10 SQUARE WAVE PULSE DURATION s Fig. 24 Maximum Transient Thermal Impedance, Junction-to-Case Vs. Pulse Ouraticn, Ali Series.