G I E SOLID STATE 1 DER 3475081 OOL?75b 4 UT 3875081 G E SOLID STATE O1E 17756 D 7-25-49" Triacs File Number 1084 12-A Silicon Triacs 2N6342A-2N6349A Series TERMINAL DESIGNATIONS For Power Contro! and Power-Switching Applications Features: @ 800V, 125 Deg. C T, Operating @ High dv/dt and di/dt Capability m@ Low Switching Losses @ High Pulse Current Capability m@ Low Forward and Reverse Leakage B Sipos Oxide Glass Multilayer Passivation System @ Advanced Unisurface Construction w@ Precise fon Implanted Diffusion Source The 2N6342A-2N6349A series triacs are gate-controlled full- wave silicon switches utilizing a plastic case with three leads to facilitate mounting on printed-circult boards. They are intended for the control of ac loads in such applications as motor controls, light dimmers, heating controls, and power-switching systems. These devices are designed to switch from an off-state to an MAXIMUM RATINGS, Absolute-Maximum Values: cri Roe) O TOP VIEW MT 92s~39970 JEDEC TO-220AB on-state for either polarity of applied voltage with positive or negative gate triggering voltages. They have an on-state current rating of 12 amperes at a T, of 80C and repetitive off-state voltage ratings of 200, 400, 600, and 8CO volts. The plastic package design provides not only ease of mounting but also low thermal impedance, which allows operation at high case temperatures and permits reduced heat-sink size. 2N6342A 2N6343A 2N6344A 2N6345A 2N6346A 2N6347A 2N6348A 2N6349A *Vonom Ty= 4010 110C coe cece cece eee eee eens 200 400 600 800 Vv Iya) To = 80C, 83609 vec eee eect eer een eve veee 12 A For other conditions ...............cc eee eee eeeeee ___SSSSOCCCC#SS@@ Figs. 5 Itsm For one cycle of applied principal voltage * 60 Hz (sinusoidal), Tc=80C ..cc cereus ccceveene 120 A 50 Hz (sinusoidal), Tc= 80C ooo. e cece eens 113 A For more than one cycle of applied principal voltage .... See Fig, 6 di/dt Vo= Vorom ler 200 MA, te=O.1 US ces ceceeeeeseeee 100 A/us [2t [At T, shown for lrigus): half-sine wave]: tHTOMS 20. eee eee cette cent eee eneenes 64 As FS QEMS coc cccccecsescnceveccvceeveteesecenens 40 As FOS MS oo cee cece ec eee cece cet e cet e ete eaeaenes 23 As * STtOB SMS cece icc ee cee cee ee eee sen cneeeees 40 As ler FOr 1S MAK. ices ere e cence cere eet eaeeneneas 4 A *Pon (For ts max. lemmS4A ccc cece eset ee eet eeeee 20 Ww *Patayy ce ee eens tereee eves Sereerenee pee eeeearerace 06 Ww "Teg ccc ccc cer eeteeetetennerecenesacereseareteneas -40 to 160 ___ C "TG cece ccc ccn cee e cree e cere eee eee recensaaeeeenses -40to 110 __ C Tz During soldering for 105 Max. ..-eecseeereeseeeeees 230 C In accordance with JEDEC registration data format JC-22 RDF-2. . For either polarity to main terminal 2 voltage (Vy72) with reference to main terminal 1. "For either polarity to gate voltge (Vq) with reference to main terminal 1. 763 1299 B- 06.G E SOLID STATE 3875081 GE SOLID STATE Trlacs O1 DE ff 3875081 001775? b I O1E 17757. D T2S-/S 2N6342A-2N6349A Series ELECTRICAL CHARACTERISTICS At Maximum Ratings Uniess Otherwise Specified, and at indicated Temperatures LIMITS For All Types . CHARACTERISTIC Except as Specified UNITS i Min. | Typ. Max. : lonam Ty = 110C, Vorom = Max, rated value _ - 2 mA Vau@ i; = 17A (peak), T, = 25C _ 13 1.75 v hno : Gate open, Initial principal current = 200 mA Vp = 12V, Te = 25C _ 6 40 mA =-40C = -_ 75 dv/dte (Commutating) Vo = Vorom: Ia = 17A, di/dt = 6.5A/ms. T, = 80C _ 5 _ dv/dte (Off-State) Vp = Vorom Te = 100C Vius 2N6342A, 2N6346A 100 300 _ 2N6343A, 2N6347A 75 250 _ 2N6344A, 2N6348A .... 60 200 _ 2N6345A, 2N6349A 30 70 - lqr@l Vp = 12V (de), R, = 1009 Mode Var Ve _ + + + _ 6 50 T.= 26C = 111- - - _ 10 50 i- + - (2N6346A-49A only) _ 6 75 411+ - + (2N6346A-49A only) - 25 75 mA i+ + + _ _ 100 T.=-40C = 111- - - _ _ 100 i- + - (2N6346A-49A only) - _ 125 Wit = + (2N6346A-49A only) _ _ 125 Ve1m Vp = 12V (dc), Rp = 100 Mode Vy. Ve 1+ + + _ 0.9 2 Te = 25C 111- - - _ 44 2 1- + ~ (2N6346A-48A only) _ 0.9 2.5 1Wi+ - + (2N6346A-48A only) _ 1.4 2.5 1+ + + _ _ 2.5 To=-40C 111- - - _ _ 2.5 1- + - (2N6346A-49A only) _ _ 3 Vv 41+ - + (2N6346A-49A only) - _ 3 Vp = Vorom Ry = 10K Q i+ + + 0.2 _ _ T,=110C = 111- ~ - 0.2 _ _ 1- + - (2N6346A-49A only) 0.2 _- _ 111+ - + (2N6346A-49A only) 0.2 _ - tor Vo = Vorom lar = 120mA, t, = 0.1 4s, i, = 17A {peak), Ty = 26C _ 1.6 2 ps Rac _ - 2 CWW In accordance with JEDEC registration data format JC-22 RDF2. For either polarity of main terminal 2 voltage (Vyrr2) with reference to main termina! 1. For either polarity of gate voltage (Vg) with reference to main terminal 1. ee 07 1300 BT8"G E SOLID STATE rere 1 eter Cn enti eR LR 3875081 G E SOLID STATE Oo. DE ff 3875081 1017758 & I oie 17758 > 4 IS Triacs AVERAGE POWER DISSIPATION MAXIMUM ALLOWABLE CASE TEMPERATURE 2 QUADRANT Th maT Temamat 2 OFF STATE WE QUADRANT OFF STATE Th -1 92LS - 2214R7 NO. II MAIN TERMINAL 2 oy, NEGATIVE STATE Fig. 1 Principal voltage-current characteristic. tr oe @= CONDUCTION ANGLE + FULL-CYCLE AMS ON-STATE CURRENT [Z7(Rms}] A Fig. 3 ~ Power dissipation as a function of rms on-state current. 92CS-30365 CURRENT WAVEFORM SINUSOIDAL LOAD: RESISTIVE OR INDUCTIVE CONDUCTION ANGLE(6)}:360 TEMPERATURE MEASURED AS SHOWN IMENS RY. SUTCINE pIONAL Ye Uf Sy SS. Iw (Te)9e 8 A 2 4 10 12 {4 FULE-CYCLE RMS ON-STATE CURRENT [I7ams)}] A Fig. 5 Maximum allowable case-temperature as @ function of rms on-state current. 9268-30363 2N6342A-2N6349A Series J r Z 8+ 35. So, VY Loe 8 7 y ar WW 9 CONDUCTION ANGLE CURRENT WAVEFORM SINUSOIDAL LOAD: RESISTIVE OR NNDUCTIVE CONDUCTION ANGLE(9) 360 CASE TEMPERATURE (Te)#llOC Q 2 4 6 8 lo 1a 4 FULL-CYCLE AVERAGE ON-STATE CURRENT (ZI T(avi] G Teal 9205-30364 Fig. 2 Power dissipation as a function of average on-state current. AVERAGE POWER DISSIPATION (Pp}W CURRENT WAVEFORM'SINUSOIDAL LOAD: RESISTIVE OR INDUCTIVE CONDUCTION ANGLE(@);360 TEMPERATURE MEASURED AS SHOWN ON DIMENSIONAL OUTLINE WKY | AF WN AN @= CONDUCTION ANGLE 0 19 2 14 FULL-CYGLE AVERAGE ON- STATE CURRENT [Zyiqy)]|A 92CS- 30372 Fig. 4 Maximum allowable case-temperature as a function of average on-state current. Lr FA MAXIMUM ALLOWABLE CASE TEMPERATURE E CONTROL MAY BE fost OURING AND IMMEDIATELY FOLLOWING SURGE CURRENT 2 INTERVAL ot OVERLOAD MAY NOT BE I REPEATED UNTIL JUNCTION == TEME URE HAS RETURNED fa TO STEADY-STATE RATED VALUE. Wes Pe ou 0 H, aS Qo 50n0 7 Ppt ut iz | Beg = ac se 2 | SUPPLY FREQUENCY: SO/60Hs SINE WAVE 4/LOAD RESISTIVE CASE TEMPERATURE (Tc ]#80C 5| RNS ON- STATE CURRENT [Ertewsilriea 10 SURGE CURRENT ouRATION FULL CYCLES 9208-30366 Fig. 6 Peak surge on-state current as a function of surge current duration. 765 1301 B-08aN AT wala Sl TREN Se G E SOLID STATE 3875081 G E SOLID STATE Triacs 2N6342A-2N6349A Series a < 1 = a z Ss FUSING CURRENT TIME (t) ms 92CS-30358 Fig. 7 Peak surge on-state current and fusing current as a function of time. r-) = g - z wu 2 & 2 a a 2 we q 3 i CASE TEMPERATURE (To}*C 9205-30365 Fig. 9 Normalized holding current as a function of case temperature. {PRINCIPAL 0 VOLTAGE I2V %& | LoAbs100n RESISTIVE | tatcserina WoDES aLt = 3 2 3 wz a S a oy = 4 w 3 be aa ul N 3 z 5 4 3} =60 -40 -20 20 40 60 60 KO BO 140 ; - CASE TEMPERATURE (TeI-"C soe sos70 Fig. 11 Normalized gate trigger voltage as a function of case temperature. 766 o1 DE fj 3875081 Oo17759 g i OIE 17759 Db T~ WS 04 08 12 16 2 24 26 32 36 4 4 POSITIVE OR NEGATIVE INSTANTANEOUS ON=STATE VOLTAGE {v 7I-V Fig. 8 On-state current as a function of on-state voltage. 9203-30367 PRINCIPAL DC VOLTAGE 12V LOADs(OON RESISTIVE TRIGGERING MODES: ALL 60 -40 -20 O 20 CASE TEMPERATURE (To}*C 40 60 60 e2e8~ 30369 Fig. 10 Normalized gate trigger current ase function of case temperature. o ' 19 toz 108 104 TIME (1}ms 9203-30371 Fig. 12 Normalized transient thermal resistance as a function of time. 1302 B-09G E SOLID STATE OL deff sa7soai oo177b0 b ff 3875081 GE SOLID STATE oie 17760 0 Tres -lS Triacs 2N6342A-2N6349A Series ' l SUPPLY | VOLTAGE 7 y, \ I o ; I i I 1 | i . j |-avat o-L- ~-- SSS - + | | | | PRINCIPAL I \ CURRENT | TT ene / ai/dt bo / . . ~ dal COMMUTATING dv/dt l | | | [ I | | | 4 | | | I | --- L --- I PRINCIPAL | VOLTAGE } COMMUTATING | wat 92LS-2409R4 1 9208-17063 Fig. 13 Relationship between supply voltage and Fig. 14 Rate-of-change of on-state current principal current (inductive load) showing with time (defining di/dt). reference points for definition of commu- tating voltage (dv/dt). tre ig + tr 92CS-IS3GERZ Fig. 15 Relationship between off-state voltage, on-state current, and gate-trigger voltage showing reference points for definition. of turn-on time tg). 767 1303 B-10