G SOLID STATE O14 DE ff 3a75081 0017752 7 , 3875081 G E SOLID STATE DiE 17752. OD T-25~ C3 Triacs File Number 414 2N5754-2N5757 2.5-A Silicon Triacs Features: a Gate sensitivity - 25 mA = di/dt capability - 100 A/ps TERMINAL DESIGNATIONS a Low switching losses = Low-on-state voltage at high current levels GATE Voltage 100 V 200 V 400 V 600 V wri un Package Types Types Types Types e2Cd-27 786 Modified TO-205 2N5754 | 2N5755 | 2N5756 | 2N5757 MODIFIED TO-205 These RCA triacs are gate-controlled full-wave silicon ac switches that are designed to switch from an off-state to an on-state for elther polarity of appliad voltage with positive or negative gate triggering voltages. The gate sensitivity of these triacs permits the use of economical transistorized control circuits and enhances their use in low-power phase control and load-switching applications. MAXIMUM RATINGS, Absolute-Maximum Values: For operation with sinusoidal supply voltage at frequencies up to 50/60 Hz and with resistive or inductive load 2NS754 2N5755 2N5766 2N5757 * Vonou A . Gate open, Ty =-65 to 100C 2... cece teen ene revere encores 100 200 400 600 Vv : trams: (@ = 360C) i To = 70C wo cseccereves 2.5 A : For other conditions See Figs. 2, 3,4 | trem For one cycle of applied principal voltage, at current and temperatura shown above for {riaus . 60 Hz (sinusoidal) ....... daenees ve 25 A 50 Hz (sinusoidal) vee 2t A | For more than one cycle of applied principal voltage ....... ___-_____. Sea Figs. 5, 6 di/dt Vo = Vorom lar = 50 MA, te = 0.1 pS i... cece ees s eee eeeneee 100 A/ps i it [At To shown for hans} I t= 2OMS occ cree eee ceeeeee ence ec aw ee een eet ees een eetee 43 As : t= 25 MS ....cccceeeeee 2 As ; t=O.B MS oo... ce eeee eee 1 As For other time values See Fig. 6 * fom @ For 1 pS MAK. wee cee eee et eaeteecensevace ea eeevceeneeees . 1 A Pau ' Peak (For 1 zs max., lar = 1 A (peak) .......--- 10 Ww i *Pauvi-To= 70C sessessecceceeaseesevenenteees 0.15 w { Ta= 25C. 0.05 Ww * Taig sececcores eens euenee see 6510169 Te vc ccccseseeentenenceuce Ved enseenesnae ser ecneseenneneeees -65to100 Tr During soldering for 10 s maximum at distance = 1/16 in. (1.58 mm) from seating plane...... de ceeeneenneeese deveces 225 C For Notes See Electrical Characteristic Chart a 759 1295 B-02G E SOLID STATE OL Def} se7sos, oo17753 49 i oie 17753 Do T2S-7lS 3875081 GE SOLID STATE Triacs 2N5754-2N5757 ELECTRICAL CHARACTERISTICS, At Maximum Ratings Unless Otherwise Specified and at indicated Case Temperature (Tc) LIMITS CHARACTERISTICS ALL TYPES UNITS MIN. TYP. MAX. . lorom A Gate open, Ts = 100C, Vorom = Max. rated value - 0.2 0.75 mA . Via A (See Fig. 7) ly = 10 A (peak), Te = 25C - 2.2 26 v iy = 3.5 A (peak), Te = 26C _ - 1.8 luo A (See Fig. 8) Gate open, Initial principal current = 150 mA (dc), Vo=12 V Te = 25C - 6 35 mA Te = -65C - 20 82 . dv/dt (Commutating) A Vp = Vorom, (riame = 2.54 commutating di/dt = 1.33 A/ms, gate unenergized, Tc = 70C 0.5 _ - V/s dv/dt (Off-State) A Vo = Vorom, exponential voltage rise, gate open, Tc = 100C 10 100 - Vips larA@ Vo = 12 V de, Ri = 30 9, To = 25C Mode Vur2 Va i* positive positive 5 25 Ur negative negative 5 25 Ir positive negative _ 10 40 Ht negative _ positive 10 40 mA Vp = 12 V de, Ri = 30 Q, Te = -65C Mode Vesta Ve {(* positive positive - 30 60 Tr negative negative - 30 60 | : Ir positive negative ~ 40 100 * { * iit negative _ positive - 40 100 * | Var Ae (See Fig. 10) { Vo = 12 V de, Ri = 30 9, Te = 25C - 0.9 2.2 Vp = 12 V de, Ri = 30 0, Te = -65C - 15 3* Vv | Vo = Vonom, Ri = 125 Q, Te = 100C 0.2 _ - tor Vo = Vorom, la = 60 mA, tr = 0.1 gs, Ir = 10 A (peak) Te = 25C _ 18 2.5 us - R6sc Steady-State - _ 8.5 cow Roa i Steady-State - - 150 * In accordance with JEDEC registration data format JS-14, RDF-2 - filed for the JEDEC (2N-Series) types. A For either polarity of main terminal 2 voltage (Varz) with reference to main terminal 1. For either polarity of gate voltage (Va) with reference to main terminal 1. 760. 1296 -03G E SOLID STATE 3875081 GE SOLID STATE. Oo De fp 3075082 oo17754 0 i DiE 17754 o7T-ZS" /35 Triacs ei ony et sean FULL-CYCLE RMS ON-STATE CURRENT [TriMUSI]A g2cs-iszien Fig. 1 - Power dissipation vs. on-state current, COOLED, 400 TO 1000 FT/MIN,HEAT RAOIATOR ATTACHED TRIAC. WITH HEAT RADIATOR TRIAC, NO HEAT RADIATOR, PRINTED-CIRCUIT BOARD MOUNTED wl am are oe 3 Zz tq 26 20 2s Ro ar =z current. er rncinnenitan arrermnem ne HEAT RADIATOR FULL-CYCLE RMS ON-STATE CURRENT [IT (RMS}]A S2L$-2097R4 Fig. - Maximum allowable ambient temperature vs. on-state SUPPLY FREQUENCY 50/60 Hz LOAD: RESISTIVE w RMS OH-STATE CURRENT (It(rusi} 2 5A] = CASE TEMPERATURE [T)= 70C jij i ty 2 rrr Tv rt g< GATE CONTADL MAY BE LOST DURING ANO "| v= IMMEDIATELY FOLLOWING SURGE CURRENT 44 : ea CX INTERVAL. i ER aN OVERLOAD MAY NOT BE REPEATED UNTIL 4 go TINK WUNCTION TEMPERATURE HAS RETURNED TO zs STEADT~ STATE RATED VALUE, rT 2 sl B 1 : se 25 NY | Pied ho | 0 #2 : ee = sone ~L , ee 9 0 wo? 0 SURGE CURRENT OURATIONFULL CYCLES . 9208-1S7SIM1 Fig. 5 - Peak surge on-state current vs. surge-current duration. eer 1297 MAXIMUM ALLOWASLE HEAT SINK 2N5754-2N5757 GURRENT WAVEFORM SINUSOIDAL LOAO RESISTIVE OR INDUCTIVE ANGLE (#):Se0 CONDUCTION i) CASE TEMPERATURE (Tp) MEASURED AS SHOWN ON DIMENSIONAL OUTLINE $ TEMPERATURE (1) -"C 3s. 38 MAXWOUM ALLOWABLE CASE FULL-CYCLE ANS ON-STATE CURRENT [Iy(AMS}}A g2is-isne Fig. 2 - Maximum allowable case temposrature vs. on-state current. NT WAVEFORM CURRE! LOAD} RESISTIVE WE CONDUCTION ANGLE (@}:360 TEMPERATURE C HEAT Si. TEMPER ~ ATURE MEASURED sam LA FROM CASE CAP. Le WGTH =|" FULL=CYCLE RMS ON-STATE CURRENT [ZT(RMSI]A g2isis90n3 Fig. 4 - Maximum allowable heat-sink temperature vs. on-state current. FUSING CURRENT FOR DEVICE < A % : 8 z TIME (t)ms 4208-27430 Fig. 6 - Peak surge on-state current and fusing current vs. time. 761 B-04prem eT Hn G E SOLID STATE Oo. DEP) 375081 0017755 2 [ annette 3875081 G E SOLID STATE oie 17755 od T=287!13 Triacs 2N5754-2N5757 CASE TEMPERATURE (Tele 25C HOLDING CURRENT (THo) mA (POSITIVE OR NEGATIVE) oc ' POSITIVE OR NEGATIVE INSTANTANEOUS T d2es-1s7isa1 CASE TEMPERATURE (Te)* secetsraea Fig. 7 - On-state current vs, on-state voltage. Fig. 8- DC holding current (positive or negative) vs. case temperature. TRIGGERING MODES 7: ALL DC VOLTAGE ={2 LOAD 30 A, RESISTIVE 4 1 5 a 5 = iy @ 5 3S = a s 2 = - w s 8 d> gH 9 ee 33 te eg ie $2 CASE TEMPERATURE {To} *C CASE TEMPERATURE (Tc) "C stes-tsrans s2c8- 1872681 Fig. 9 - DC gate-trigger current vs. case temperature. Fig. 10 - DC gate-trigger voltage vs. case tamperature.