Internally Triggered Triacs (4 a to 15 A)

WWW.100Y.COM.TW

9 WWW.100Y.COM.TW

U.L. RECOGNIZEDFile #E7163 WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW TO-220 WWW.100Y.COM.TWIsolated WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW MT2 MT1 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW T WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW Internally Triggered Triacs (4 A to 15 A) WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

E3 WWW.100Y.COM.TW General DescriptionWWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW Teccor ’s QuadracWW devicesW.100 areY.COM.TW triacs that include a diac trigger All Teccor triac and diac chips have glass-passivated junctions to mounted inside the same package. This device, developed by ensure long-term device reliability and parameter stability. WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW Teccor, saves the user the expense and assembly time of buying Variations of devices in this data WW sheetW are.100 availableY.COM.TW for custom a discrete diac andWW assemblingW.100Y in.COM.TW conjunction with a gated triac.WW W.100designY.COM.TW applications. Consult the factory for more information. Also, the alternistor Quadrac device (QxxxxLTH) eliminates the WWW.100Y.COM.TW WWW.100Y.COM.TW need for a snubber WWnetwork.W.100Y.COM.TW

The Quadrac deviceWW is a bidirectionalW.100Y.COM.TW AC switch and is gate con-WWW.100Y.COM.TW WWW.100Y.COM.TW trolled for either polarity of main terminal voltage. Its primary pur- WWW.100Y.COM.TW WWW.100Y.COM.TW pose is for AC switchingWW andW phase.100 Ycontrol.COM.TW applications such as speed controls, temperature modulation controls, and lighting WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW controls where noise immunity is required. WWW.100Y.COM.TW WWW.100Y.COM.TW Triac current capacities rangeWW fromW.100 4 AY to.COM.TW 15 A with voltage Features ranges from 200 V to 600 V. Quadrac devices are available in the WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW TO-220 package. • Glass-passivated junctions • Electrically-isolated package The TO-220 package is electricallyWWW isolated.100Y .COM.TWto 2500 V rms from WWW.100Y.COM.TW WWW.100Y.COM.TW • Internal trigger diac the leads to mounting surface. 4000 V rms is available on special WWW.100Y.COM.TW WWW.100Y.COM.TW order. This means that no externalWW isolationW.100 Yis.COM.TW required, thus • High surge capability — up to 200 A

eliminating the need for separateWW insulatorsW.100 andY.COM.TW insulator-mount- •WW HighW .100voltageY.COM.TW capability — 200 V to 600WW V W.100Y.COM.TW ing steps and saving dollars over “hot tab” devices. WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW

Quadrac Data Sheets WWW.100Y.COM.TW

WWW.100Y.COM.TW

WWW.100Y.COM.TW Part No. Trigger Diac Specifications (T–MT1) WWW.100Y.COM.TW IT(RMS) IsolatedWWW.100VYDRM.COM.TW IDRM VTM V V [VM ]I C BO BO BO T (5) WWW.100(1)Y.COM.TW(1) (10) WW(1)W (3).100Y.COM.TW(7) (6) (6) (11)

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WWW.100Y.COM.TW WWW.100Y.COM.TW T WWW.100Y.COM.TW MT1 MT2 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW mAmps Volts

WWW.100Y.COM.TW WWW.100TYC .COM.TW= TC = TC = WWW.100Y.COM.TW TO-220 Volts 25 °C 100 °C 125 °C T = 25 °C Volts Volts Volts µAmps µFarads C WWW.100See Y“Package.COM.TW Dimensions” section WWW.100Y.COM.TW WWW.100Y.COM.TW for variations. (12) MIN MAX MAX MAX MIN MAX MIN MAX MAX WWW.100Y.COM.TW WWW.100Y.COM.TWQ2004LT WW200 W.1000.05Y.COM.TW0.5 2 1.6 3 33 43 5 25 0.1 4A Q4004LT 400WWW.1000.05 Y.COM.TW0.5 2 1.6 WWW3 .100Y33.COM.TW43 5 25 0.1 WWW.100Y.COM.TWQ6004LT 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1

Q2006LT 200WWW 0.05.100Y 0.5.COM.TW 2 1.6WW 3W.100 33Y.COM.TW 43 5 25 0.1 WWW.100Y.COM.TW Q4006LT 400 0.05 0.5 2 1.6 3 33 43 5 25 0.1 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 6A Q6006LT 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1 Q4006LTH 400 WW 0.05W.100 0.5Y.COM.TW 2 1.6WW 3W.100 33Y.COM.TW 43 5 25 0.1 WWW.100Y.COM.TW Q6006LTH 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1 WWW.100Y.COM.TWQ2008LT 200 WW0.05W.1000.5 Y.COM.TW2 1.6 WW3 W33.100Y43.COM.TW5 25 0.1

Q4008LT 400 WW0.05 W.1000.5 Y.COM.TW2 1.6 3WWW33.10043Y.COM.TW5 25 0.1 WWW.100Y.COM.TWQ6008LT 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1 8A WWW.100YQ4008LTH.COM.TW 400 0.05WWW0.5.100Y.COM.TW2 1.6 3 WW33W.10043 Y.COM.TW5 25 0.1

Q6008LTH 600 0.05 0.5 2 1.6 3 WW33 W.10043 Y.COM.TW5 25 0.1 WWW.100YQ2010LT.COM.TW 200 0.05WW 0.5W.100Y 2.COM.TW 1.6 3 33 43 5 25 0.1

Q4010LT 400 0.05 WW 0.5W.100 2Y.COM.TW 1.6 3WW 33W 43.100Y.COM.TW 5 25 0.1 WWW.100Y.COM.TW 10 A Q6010LT 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1 WWW.100Q4010LTHY.COM.TW 400 0.05WW 0.5W.100 2Y.COM.TW 1.6 3 33WWW 43.100Y 5.COM.TW 25 0.1

Q6010LTH 600 0.05 WW 0.5W.100 2Y.COM.TW 1.6 3 33WW 43W.100 5Y.COM.TW 25 0.1 WWW.100Q2015LTY.COM.TW200 0.05 0.5 2 1.6 3 33 43 5 25 0.1

WWWQ4015LT.100Y.COM.TW400 0.05 0.5WWW2.100Y.COM.TW1.6 3 33 WW43 W.1005 Y.COM.TW25 0.1 Q6015LT 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1 15 A WWW.100Y.COM.TW WWQ4015LTHW.100Y.COM.TW400 0.05 0.5WWW2 .100Y.COM.TW1.6 3 33 43 5 25 0.1

Q6015LTH 600 0.05 0.5 2 1.6 3 33 43 5 25 0.1 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100VDRMY —.COM.TW Repetitive peak blocking voltage Specific Test Conditions V — Peak on-state voltage at maximum rated RMS current WWW.100TM Y.COM.TW WWW.100Y.COM.TW V±] — Dynamic breakbackWWW voltage.100 Y(forward.COM.TW and reverse) VBO — Breakover voltage symmetry WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW General Notes CT — Trigger firing capacitance WWW.100Y.COM.TW WWW.100Y.COM.TW di/dt — Maximum rate-of-changeWWW of.100 on-stateY.COM.TW current • All measurements are made at 60 Hz with resistive load at an ambient temperature of +25 LC unless otherwise specified. dv/dt — Critical rate-of-rise of off-state voltage at rated VDRM gate open WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW L L dv/dt(c) — Critical rate-of-rise of commutation voltage at rated V DRM • Operating temperature range (T J) is -40 C to +125 C. and I commutating di/dt = 0.54 rated I /ms; gate WWW.100Y.COM.TW L WWWL.100Y.COM.TW T(RMS) WWW.100Y.COM.TWT(RMS) • Storage temperature range (TS) is -40 C to +125 C. unenergized •WW LeadW solder.100Y temperature.COM.TW is a maximum of +230WWLCW for.100 10 secondsY.COM.TW 2 WWW.100Y.COM.TW I t — RMS surge (non-repetitive) on-state current for period of 8.3 ms maximum; O1/16" (1.59 mm) from case. for fusing WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW • The case temperature (TC) is measured as shown on dimensional IBO — Peak breakover current WWW.100Y.COM.TW outlineWWW drawings..100Y .COM.TWSee “Package Dimensions” sectionWW Wof .100this Y.COM.TW IDRM — Peak off-state current gate open; VDRM = maximum rated value catalog. WWW.100Y.COM.TW IGTM — Peak gate trigger current (10WWµs Max)W.100Y.COM.TW WWW.100Y.COM.TW IH — Holding current; gate open WWW.100Y.COM.TW ElectricalWW WSpecification.100Y.COM.TW Notes WWW.100Y.COM.TW IT(RMS) — RMS on-state current, conduction angle of 360° (1) For either polarity of MT2 with reference to MT1 WWW.100Y.COM.TW ITSM — Peak one-cycle surge WWW.100Y.COM.TW WWW.100Y.COM.TW t — Gate controlled turn-on time (2) See Figure E3.1 for IH versus TC. gt WWW.100Y.COM.TW WWW.100Y.COM.TW VBO — Breakover voltage (forward and reverse) (3) See Figure E3.4 and Figure E3.5 for iT versus vT. WWW.100Y.COM.TW (4) See FigureWW E3.9W for.100 surgeY.COM.TW ratings with specific durations.

WWW.100Y.COM.TW WWW.100Y.COM.TW

Data Sheets Quadrac WWW.100Y.COM.TW

WWW.100Y.COM.TW

WWW.100Y.COM.TW I I t 2 I H TSM dv/dt(c) dv/dt WWW.100gt Y.COM.TWI t GTM di/dt (1) (2) (4)WW (8) W.100Y(1).COM.TW (5) (8) (1) (6) (9) (9)

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WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TWVolts/µSec

T = T = WWW.100Y.COM.TWC C WWW.100Y.COM.TW2 WWW.100Y.COM.TWmAmps Amps Volts/µSec 100 °C 125 °C µSec Amps Sec Amps Amps/µSec

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW MAX 60/50Hz MIN MIN TYP

40 55/46 WW3 W.100Y.COM.TW75 50 3 WWW.10012.5Y.COM.TW 1.2 50 WWW.100Y.COM.TW 40 55/46 3 75 50 3 12.5 1.2 50 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y40.COM.TW55/46 3 50 50 3 12.5 1.2 50

WWW.10050Y.COM.TW 80/65WW 4W.100Y 150.COM.TW 100 3WWW.100 26.5Y.COM.TW 1.5 70 50 80/65 4 150 100 3 26.5 1.5 70 WWW.100Y.COM.TW WWW.10050Y.COM.TW 80/65 4WWW.100 125Y.COM.TW 85 3 26.5 1.5 70

50 80/65 25 575 450 3 26.5 1.5 70 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 50 80/65 25 425 350 3 26.5 1.5 70

60 100/83 4 WWW.100175 Y.COM.TW120 3 WWW41 .100Y.COM.TW1.5 70 WWW.100Y.COM.TW 60 100/83 4 175 120 3 41 1.5 70 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW60.100Y.COM.TW100/83 4 150 100 3 41 1.5 70

WW60W.100Y.COM.TW100/83 25 WW575W.100450Y.COM.TW3 WW41 W.100Y.COM.TW1.5 70 60 100/83 25 425 350 3 41 1.5 70 WWW.100Y.COM.TW WW60W.100Y 120/100.COM.TW 4WW 200W.100 150Y.COM.TW 3 60 1.5 70

60 120/100 4 WW 200W.100 150Y.COM.TW 3 60WWW.100Y.COM.TW 1.5 70 WW60W.100 120/100Y.COM.TW 4 175 120 3 60 1.5 70

60 120/100 30WW 925W 700.100Y.COM.TW 3 60WWW.100Y.COM.TW 1.5 70 WWW.100Y.COM.TW 60 120/100 30 775 600 3 60 1.570 WWW.100Y.COM.TW WWW.100Y.COM.TW 70WWW.100200/167Y.COM.TW 4 300 200 3 166 1.5 100

70 WWW200/167.100Y.COM.TW4 300WW200W.100Y.COM.TW3 166 WWW.1001.5Y.COM.TW 100 70 200/167 4 200 150 3 166 1.5 100 WWW.100Y.COM.TW WWW.100Y.COM.TW 70 WWW200/167.100Y.COM.TW30 925 700 3 166 1.5 100 70 200/167 30 775 600 3 166 1.5 100 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW (5) See FigureWW E3.6,W Figure.100 E3.7,Y.COM.TW and Figure E3.8 for current rating at Electrical Isolation specific operating temperature. WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW (6) See Figure E3.2 and Figure E3.3 for test circuit. All Teccor isolated Quadrac packages withstand a minimum high potential test of 2500 V ac rms from leads to mounting tab over (7) VBO = [+ VBO] - [- VBO] WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW the operating temperature range of the device. The following iso- (8) See Figure E3.7 and Figure E3.8 for maximum allowable case WWW.100lationY table.COM.TW shows standard and optionalWWW isolation.100Y.COM.TW ratings. temperature at maximumWWW.100 ratedY current..COM.TW

(9) Trigger firing capacitanceWWW =.100 0.1 µFY.COM.TW with 0.1 µs rise time WWW.100Y.COM.TW Electrical IsolationWWW .100Y.COM.TW (10) T = T for test conditions in off state from Leads to Mounting Tab * C J WWW.100Y.COM.TW WWW.100Y.COM.TW (11) Maximum required WWvalue Wto ensure.100Y sufficient.COM.TW gate current VACRMS TYPE

(12) See package outlinesWW for leadW .100form configurations.Y.COM.TW When ordering WWW.100Y.COM.TW2500 WWWStandard.100Y.COM.TW special lead forming, add type number as suffix to part number. 4000 Optional ** WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW * UL Recognized File #E71639

WWW.100Y.COM.TW WW**For W4000.100 V isolation,Y.COM.TW use “V” suffix in part number.WWW.100Y.COM.TW

Thermal Resistance (Steady State) WWW.100Y.COM.TW WWW.100Y.COM.TW R [RWW ] °C/WW.100 (TYP)Y.COM.TW JC JA TYPEWWW.100 IsolatedY.COM.TW TO-220 WWW.100Y.COM.TW WWW.100Y.COM.TW

4A 3.6 [50] WWW.100Y.COM.TW WWW.100Y.COM.TW 6AWWW.100Y.COM.TW 3.3

8A WWW.100Y2.8.COM.TW WWW.100Y.COM.TW 10 A 2.6 15 A WWW.1002.1Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW

Quadrac Data Sheets WWW.100Y.COM.TW

WWW.100Y.COM.TW

WWW.100Y.COM.TW 20 WWW.100Y.COM.TW WWW.100Y.COM.TW 18 2.0 T = 25 ˚C C WWW.100INITIALY .COM.TWON-STATE CURRENT WWW.10016Y.COM.TW ) – Amps = 200 mA DC 4 A to 10 A T = 400 mA DC 15 A 14 1.5 WWW.100Y.COM.TW WWW.100Y.COM.TW 6 A, 8 A, and 10 A 12 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TWH I = 25 ˚C) 10 1.0 C WWW.100Y.COM.TW WWW.100Y.COM.TW(T WWW.100Y.COM.TW 8 H

WWPositive or Negative W.100Y.COM.TW WWW.100Y.COM.TW.5 WWW.100Y.COM.TW 6

WWW4 .100Y.COM.TW WWW.100Y.COM.TW 4 A WWW.100Y.COM.TWRatio of

0 2 WWInstantaneous On-state Current (i W.100Y.COM.TW WWW.100Y.COM.TW-40 -15 +25WWW.100 +65Y.COM.TW +105 +125 0 0 0.6 0.8 1.0 1.2 1.4 1.6 WWW.100Y.COM.TW Case TemperatureWWW (TC.100) – ˚CY.COM.TW WWW.100Y.COM.TW Positive or Negative Instantaneous On-state Voltage (v ) – Volts WWW.100Y.COM.TW WWW.100Y.COM.TW T WWW.100Y.COM.TW

WWFigureW E3.1.100Y Normalized.COM.TW DC Holding CurrentWW versusW Case.100 TemperatureY.COM.TW Figure E3.4 On-stateWWW Current.100Y versus.COM.TW On-state Voltage (Typical) (4 A to 10 A) WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 90 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 80 R L TC = 25˚C ) – Amps WWW.100Y.COM.TW T 70 WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW D.U.T.WWW.100MT2 Y.COM.TW 60 WWW.100Y.COM.TW

50 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 15 A 40 120 V WWW.100Y.COM.TW 60 HzWWW.100Y.COM.TW WWW.100Y.COM.TW 30 Positive or Negative WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TWT 20

WWW.100Y.COM.TW10 WWW.100Y.COM.TW WWW.100Y.COM.TW VC Instantaneous On-state Current (i MT1 0 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW0 0.6 0.8 1.0 1.2 1.4 1.6 1.8 CT = 0.1 µF PositiveWW or WNegative.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW Instantaneous On-state Voltage (vT) – Volts

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW Figure E3.2 Test Circuit Figure E3.5 On-state Current versus On-state Voltage (Typical) (15 A) WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW120

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW ) – ˚C VC A 100 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW +VBO 4 A WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW ∆V+ 80 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.10060 Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 40 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 25 ∆V- Maximum Allowable Ambient Temperature (T WWW.100Y.COM.TW WWW.100Y.COM.TW WW20W.100Y.COM.TW -VBO 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW RMS On-state Current [IT(RMS)] – Amps

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW Figure E3.3 Test Circuit Waveforms Figure E3.6 Maximum Allowable Ambient Temperature versus WWW.100Y.COM.TW WWOn-stateW.100 CurrentY.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW

Data Sheets Quadrac WWW.100Y.COM.TW

WWW.100Y.COM.TW

WWW.100Y.COM.TW 4.0 130 WWW.100YCURRENT.COM.TW WAVEFORM: Sinusoidal WWW.100Y.COM.TW LOAD: Resistive or Inductive ) – ˚C 120 CONDUCTION ANGLE: 360 C ˚ ] – Watts WWW.100CASEY.COM.TW TEMPERATURE: Measured WWW.100Y.COM.TW as shown on Dimensional Drawings 110 3.0 D(AV) WWW.100Y.COM.TW WWW.100Y.COM.TW 4 A 100 WWW.1004 A Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 90 2.0 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 80 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

70 WWW.1001.0 Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW CURRENT WAVEFORM: Sinusoidal

600 LOAD: Resistive or Inductive WWW.100Y.COM.TW WWW.100Y.COM.TWCONDUCTION ANGLE: 360˚

WWW.100Y.COM.TWMaximum Allowable Case Temperature (T

Average On-state Power Dissipation [P 0 0 .5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 0 1.0 2.0 3.0 4.0 5.0 RMS On-state Current [I ] – Amps T(RMS) RMS On-state Current [IT(RMS)] – Amps WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

Figure E3.7 Maximum Allowable Case WWTemperatureW.100 versusY.COM.TW Figure E3.10WW PowerW.100 DissipationY.COM.TW (Typical) versus On-state Current (4 A) WWW.100Y.COM.TWOn-state Current (4 A)

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW 18 130 CURRENT WAVEFORM: Sinusoidal LOAD: ResistiveWW or WInductive.100Y.COM.TW 16 WWW.100Y.COM.TW WWW.100) – ˚C 120Y.COM.TW CONDUCTION ANGLE: 360 C ˚ CASE TEMPERATURE: Measured ] – Watts as shown onWW DimensionalW Drawings.100Y.COM.TW 14 WWW.100Y.COM.TW WWW.100110 Y.COM.TW D(AV)

WWW.100Y.COM.TW WWW.100Y.COM.TW 12 WWW.100Y.COM.TW 100 15 A 10 6 A WWW.100Y.COM.TW WWW.100Y.COM.TW15 A WWW90.100Y.COM.TW 6 A to 10 A WWW.100Y.COM.TW 8 WWW.100Y.COM.TW WWW80 .100Y.COM.TW 10 A 8 A WWW.100Y.COM.TW 6 WWW.100Y.COM.TW WW70W.100Y.COM.TW 4 WWW.100Y.COM.TW WWW.100Y.COM.TW WW60 W.100Y.COM.TW CURRENT WAVEFORM: Sinusoidal 2 LOAD: Resistive or Inductive

Maximum Allowable Case Temperature (T WWW.100CONDUCTIONY.COM.TW ANGLE: 360˚ WW0 W.100Y.COM.TW WWW.100Y.COM.TW Average On-state Power Dissipation [P 0 2.0 4.0 6.0 8.0 10.0 12.0 14.0 16.0 18.0 20.0 0 WWW.100Y.COM.TW 0 2 4 WW6 W.1008 Y10 .COM.TW12 14 16 WWW.100RMSY On-state.COM.TW Current [IT(RMS)] – Amps RMS On-state Current [I ] – Amps T(RMS) WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW Figure E3.8 Maximum Allowable Case Temperature versus Figure E3.11 Power Dissipation (Typical) versus On-state Current WWW.100Y.COM.TW WWW.100Y.COM.TW On-stateWWW Current.100 Y(6.COM.TW A to 15 A) (6 A to 10 A and 15 A)

WWW.100Y.COM.TW WWW.100Y.COM.TW WWW.100Y.COM.TW

200 WWW.100Y.COM.TW WWW.100Y.COM.TWNOTES: WWW.100Y.COM.TW+4 1) Gates control may be lost during 120 and immediately following surge 100 current interval. WWW.100Y.COM.TW 2) Overload may not be repeated until WWW.100Y.COM.TW 80 WWW.100Y.COM.TW +2 junction temperature has returned to 60 steady state rated value. WWW.100Y.COM.TW 50 WWW.100Y.COM.TW WWW.100Y.COM.TW 40 0 ) – Amps Change – % 30 WWW.100Y.COM.TW 15 A WWW.100Y.COM.TW WWW.100Y.COM.TW TSM BO 20 10 A -2 WWW.100Y.COM.TW WWW.100Y.COM.TW 8 A WWW.100Y.COM.TW 6 A 10 -4 WWW.100Y.COM.TW 8 WWW.100Y.COM.TW 4 A WWW.100Y.COM.TW 6 5

Peak Surge (Non-repetitive) WWW.100Y.COM.TW 4 WWW.100Y.COM.TW WWW.100-6 Y.COM.TW On-state Current (I 3 SUPPLY FREQUENCY: 60 Hz Sinusoidal WWW.100Y.COM.TW 2 LOAD: Resistive WWW.100Y.COM.TW WWW.100Y.COM.TW Percentage of V -8 RMS ON-STATE CURRENT [IT(RMS)]: Maximum Rated Value at Specified Case Temperature -40 -20 0 +20 +40 +60 +80WW +100W +120.100+140Y.COM.TW 1 WWW.100Y.COM.TW WWW.100Y.COM.TW 1 2 3 4 5 6 8 10 20 3040 60 80 100 200 300 600 1000 Junction Temperature (T WW) – ˚CW.100Y.COM.TW Surge CurrentWW DurationW .100– Full CyclesY.COM.TW WWW.100Y.COM.TW J

Figure E3.9 Peak Surge Current versusWW SurgeW.100 CurrentY.COM.TW Duration FigureWW E3.12W Normalized.100Y.COM.TW diac V versus Junction Temperature BO WWW.100Y.COM.TW WWW.100Y.COM.TW

WWW.100Y.COM.TW WWW.100Y.COM.TW