IKFW5N6DH3E HighspeedswitchingseriesthirdgenerationIGBTcopackedwithRapid fastandsoftantiparalleldiodeinfullyisolatedpackage Features: C TRENCHSTOP technologyoffers: Shortcircuitwithstandtime5µsatTvj=75 C PositivetemperaturecoefficientinVCE(sat) LowEMI Verysoft,fastrecoveryantiparalleldiode Maximumjunctiontemperature75 C 25VRMSelectricalisolation,5/6Hz,t=min %testedisolatedmountingsurface Pbfreeleadplating;RoHScompliant CompleteproductspectrumandPSpiceModels: http://www.infineon.com/igbt G E PotentialApplications: AirConditioningPFC GeneralPurposeDrives(GPD) ServoDrives Fully isolated package TO247 ProductValidation: Qualifiedforindustrialapplicationsaccordingtotherelevanttests ofjedec47/2/22 KeyPerformanceandPackageParameters Type VCE IC VCEsat,Tvj=25 C Tvjmax Marking Package IKFW5N6DH3E 6V 4A 2.2V 75 C K5DDH3E PGTO2473AI Datasheet PleasereadtheImportantNoticeandWarningsattheendofthisdocument V2. www.infineon.com
IKFW5N6DH3E TableofContents Description........................................................................ Table of Contents................................................................... 2 Maximum Ratings................................................................... 3 Thermal Resistance................................................................. 3 Electrical Characteristics.............................................................. 4 Electrical Characteristics Diagrams..................................................... 6 Package Drawing...................................................................3 Testing Conditions..................................................................4 Revision History....................................................................5 Disclaimer.........................................................................6 Datasheet 2 V2.
IKFW5N6DH3E MaximumRatings Foroptimumlifetimeandreliability,Infineonrecommendsoperatingconditionsthatdonotexceed8%ofthemaximumratingsstatedinthisdatasheet. Parameter Symbol Value Unit Collectoremittervoltage,Tvj 25 C VCE 6 V DCcollectorcurrent,limitedbyTvjmax Th=25 Cvaluelimitedbybondwire Th=65 C Th=65 C IC 4. 37. 6. ) A Pulsedcollectorcurrent,tplimitedbyTvjmax ICpuls 2. A Turn off safe operating area VCE 6V,Tvj 75 C,tp=µs Diodeforwardcurrent,limitedbyTvjmax Th=25 Cvaluelimitedbybondwire Th=65 C 2. A IF 4. 29. Diodepulsedcurrent,tplimitedbyTvjmax IFpuls 2. A Gateemitter voltage TransientGateemittervoltage(tp µs,d<.) Short circuit withstand time VGE=5.V,VCC 4V Allowed number of short circuits < Time between short circuits:.s Tvj=5 C PowerdissipationTh=25 C PowerdissipationTh=65 C VGE tsc Ptot ±2 ±3 5 3. 95. Operating junction temperature Tvj 4...+75 C Storage temperature Tstg 55...+5 C Soldering temperature, wave soldering.6mm (.63in.) from case for s 26 Mounting torque, M3 screw, PGTO2473AI Maximum of mounting processes: 3 A V µs W C M.6 Nm IsolationvoltageRMS,f=5/6Hz,t=min 2) Visol 25 V ThermalResistance Parameter Symbol Conditions Value min. typ. max. Unit RthCharacteristics IGBT thermal resistance, 3) junction heatsink Diode thermal resistance, 3) junction heatsink Thermal resistance junction ambient Rth(jh).98.5 K/W Rth(jh).96 2.6 K/W Rth(ja) 65 K/W ) Equivalent current rating in TO2473 at Th = 65 C using reference insulation material: 52µm,.9 W/mK, standard polyimide based reinforced carrier insulator 2) For a proper handling and assembly of the advanced isolation device in the application refer to the note at the package drawing. 3) At force on body F = 5N, Ta = 25ºC Datasheet 3 V2.
IKFW5N6DH3E ElectricalCharacteristic,atTvj=25 C,unlessotherwisespecified Parameter Symbol Conditions Value min. typ. max. Unit StaticCharacteristic Collectoremitter breakdown voltage V(BR)CES VGE=V,IC=.5mA 6 V Collectoremitter saturation voltage Diode forward voltage VCEsat VF VGE=5.V,IC=4.A Tvj=25 C Tvj=75 C VGE=V,IF=2.A Tvj=25 C Tvj=75 C Gateemitter threshold voltage VGE(th) IC=.43mA,VCE=VGE 4. 5. 5.7 V Zero gate voltage collector current ICES VCE=6V,VGE=V Tvj=25 C Tvj=75 C Gateemitter leakage current IGES VCE=V,VGE=2V na Transconductance gfs VCE=2V,IC=4.A 5. S 2.2 2.8.5.45 44 2.7.9 4 V V µa ElectricalCharacteristic,atTvj=25 C,unlessotherwisespecified Parameter Symbol Conditions Value min. typ. max. Unit DynamicCharacteristic Input capacitance Cies 74 Output capacitance Coes VCE=25V,VGE=V,f=MHz 73 Reverse transfer capacitance Cres 48 Gate charge Internal emitter inductance measured 5mm (.97 in.) from case Short circuit collector current Max. short circuits Time between short circuits:.s QG VCC=48V,IC=4.A, VGE=5V pf 6. nc LE 3. nh IC(SC) VGE=5.V,VCC 4V, tsc 5µs Tvj=5 C 66 A SwitchingCharacteristic,InductiveLoad Parameter Symbol Conditions Value min. typ. max. Unit IGBTCharacteristic,atTvj=25 C Turnon delay time td(on) Tvj=25 C, 2 ns Rise time VCC=4V,IC=4.A, tr 39 ns VGE=./5.V, Turnoff delay time td(off) RG(on)=8.Ω,RG(off)=8.Ω, 74 ns Fall time Lσ=75nH,Cσ=3pF tf 8 ns Lσ,CσfromFig.E Turnon energy Eon Energy losses include tail and.28 mj Turnoff energy Eoff diode reverse recovery..56 mj Total switching energy Ets.84 mj Datasheet 4 V2.
IKFW5N6DH3E Diode reverse recovery time trr Tvj=25 C, 64 ns Diode reverse recovery charge VR=4V, Qrr.5 µc IF=2.A, Diode peak reverse recovery current Irrm dif/dt=a/µs.7 A Diode peak rate of fall of reverse recoverycurrentduringtb dirr/dt 84 A/µs SwitchingCharacteristic,InductiveLoad Value Parameter Symbol Conditions Unit min. typ. max. IGBTCharacteristic,atTvj=75 C Turnon delay time td(on) Tvj=75 C, 2 ns Rise time VCC=4V,IC=4.A, tr 37 ns VGE=./5.V, Turnoff delay time td(off) RG(on)=8.Ω,RG(off)=8.Ω, 2 ns Fall time Lσ=75nH,Cσ=3pF tf 2 ns Lσ,CσfromFig.E Turnon energy Eon Energy losses include tail and.75 mj Turnoff energy diode reverse recovery. Eoff.73 mj Total switching energy Ets 2.48 mj Diode reverse recovery time trr Tvj=75 C, 3 ns Diode reverse recovery charge VR=4V, Qrr.24 µc IF=2.A, Diode peak reverse recovery current Irrm dif/dt=a/µs 7.2 A Diode peak rate of fall of reverse recoverycurrentduringtb dirr/dt 52 A/µs Datasheet 5 V2.
IKFW5N6DH3E 4 2 IC,COLLECTORCURRENT[A] not for linear use Ptot,POWERDISSIPATION[W] 8 6 4 2. VCE,COLLECTOREMITTERVOLTAGE[V] Figure. Forwardbiassafeoperatingarea (D=,Th=25 C,Tj 75 C,VGE=5V,tp µs) 25 5 75 25 5 75 Th,HEATSINKTEMPERATURE[ C] Figure 2. Powerdissipationasafunctionofheatsink temperature (Tj 75 C) IC,COLLECTORCURRENT[A] 45 4 35 3 25 2 5 TO247 Advanced Isolation TO247 with insulator film (using same chip) IC,COLLECTORCURRENT[A] 2 9 8 7 6 5 4 3 VGE=2V 7V 5V 3V V 9V 7V 5V 2 5 25 5 75 25 5 75 Th,HEATSINKTEMPERATURE[ C] Figure 3. Collectorcurrentasafunctionofheatsink temperature (VGE 5V,Tj 75 C,insulatorfilm:52µm,.9W/mK) 2 3 4 5 VCE,COLLECTOREMITTERVOLTAGE[V] Figure 4. Typicaloutputcharacteristic (Tj=25 C) Datasheet 6 V2.
IKFW5N6DH3E 2 VGE=2V 7V 2 Tvj = 25 C Tvj = 75 C IC,COLLECTORCURRENT[A] 8 6 4 5V 3V V 9V 7V 5V IC,COLLECTORCURRENT[A] 8 6 4 2 2 2 3 4 5 6 VCE,COLLECTOREMITTERVOLTAGE[V] Figure 5. Typicaloutputcharacteristic (Tj=75 C) 4 6 8 2 4 6 VGE,GATEEMITTERVOLTAGE[V] Figure 6. Typicaltransfercharacteristic (VCE=2V) 5. VCE(sat),COLLECTOREMITTERSATURATION[V] 4.5 4. 3.5 3. 2.5 2..5 IC = 2A IC = 4A IC = 8A t,switchingtimes[ns] td(off) tf td(on) tr. 25 5 75 25 5 75 Tj,JUNCTIONTEMPERATURE[ C] Figure 7. Typicalcollectoremittersaturationvoltageas afunctionofjunctiontemperature (VGE=5V) 2 3 4 5 6 7 8 IC,COLLECTORCURRENT[A] Figure 8. Typicalswitchingtimesasafunctionof collectorcurrent (ind.load,tj=75 C,VCE=4V,VGE=/5V, RG=8Ω,testcircuitinFig.E) Datasheet 7 V2.
IKFW5N6DH3E td(off) tf td(on) tr td(off) tf td(on) tr t,switchingtimes[ns] t,switchingtimes[ns] 2 3 4 5 6 RG,GATERESISTOR[Ω] Figure 9. Typicalswitchingtimesasafunctionofgate resistor (ind.load,tj=75 C,VCE=4V,VGE=/5V, IC=4A,testcircuitinFig.E) 25 5 75 25 5 75 Tj,JUNCTIONTEMPERATURE[ C] Figure. Typicalswitchingtimesasafunctionof junctiontemperature (ind.load,vce=4v,vge=/5v,ic=4a, rg=8ω,testcircuitinfig.e) VGE(th),GATEEMITTERTHRESHOLDVOLTAGE[V] 6 5 4 3 typ. min. max. E,SWITCHINGENERGYLOSSES[mJ] 8 7 6 5 4 3 2 Eoff Eon Ets 2 25 5 75 25 5 Tj,JUNCTIONTEMPERATURE[ C] Figure. Gateemitterthresholdvoltageasafunction ofjunctiontemperature (IC=.43mA) 2 3 4 5 6 7 8 IC,COLLECTORCURRENT[A] Figure 2. Typicalswitchingenergylossesasa functionofcollectorcurrent (ind.load,tj=75 C,VCE=4V,VGE=/5V, RG=8Ω,testcircuitinFig.E) Datasheet 8 V2.
IKFW5N6DH3E 7 3. Eoff Eoff Eon Eon 6 Ets 2.5 Ets E,SWITCHINGENERGYLOSSES[mJ] 5 4 3 2 E,SWITCHINGENERGYLOSSES[mJ] 2..5..5 2 3 4 5 6 RG,GATERESISTOR[Ω] Figure 3. Typicalswitchingenergylossesasa functionofgateresistor (ind.load,tj=75 C,VCE=4V,VGE=/5V, IC=4A,testcircuitinFig.E). 25 5 75 25 5 75 Tj,JUNCTIONTEMPERATURE[ C] Figure 4. Typicalswitchingenergylossesasa functionofjunctiontemperature (indload,vce=4v,vge=/5v,ic=4a, RG=8Ω,testcircuitinFig.E) 4. 3.5 Eoff Eon Ets 6 4 VCC=2V VCC=48V E,SWITCHINGENERGYLOSSES[mJ] 3. 2.5 2..5. VGE,GATEEMITTERVOLTAGE[V] 2 8 6 4.5 2. 2 25 3 35 4 45 5 VCE,COLLECTOREMITTERVOLTAGE[V] Figure 5. Typicalswitchingenergylossesasa functionofcollectoremittervoltage (ind.load,tj=75 C,VGE=/5V,IC=4A, RG=8Ω,testcircuitinFig.E) 2 4 6 8 2 4 6 8 QGE,GATECHARGE[nC] Figure 6. Typicalgatecharge (IC=4A) Datasheet 9 V2.
IKFW5N6DH3E 4 C,CAPACITANCE[pF] E+4 Cies Coes Cres IC(SC),SHORTCIRCUITCOLLECTORCURRENT[A] 35 3 25 2 5 2 3 VCE,COLLECTOREMITTERVOLTAGE[V] Figure 7. Typicalcapacitanceasafunctionof collectoremittervoltage (VGE=V,f=MHz) 5 2 4 6 8 2 VGE,GATEEMITTERVOLTAGE[V] Figure 8. Typicalshortcircuitcollectorcurrentasa functionofgateemittervoltage (VCE 4V,startatTj=25 C) 4 tsc,shortcircuitwithstandtime[µs] 2 8 6 4 2 2 3 4 5 VGE,GATEEMITTERVOLTAGE[V] Figure 9. Shortcircuitwithstandtimeasafunctionof gateemittervoltage (VCE 4V,startatTj 5 C) Zth(jh),TRANSIENTTHERMALIMPEDANCE[K/W].. D =.5. E6 E5 E4... tp,pulsewidth[s].2..5.2. single pulse i: 2 3 4 5 6 7 ri[k/w]: 4.E3.368.9283.274.277.3778.2248 τi[s]:.8e5 2.6E4 2.2E3.7983.2473.99 5.985 Figure 2. IGBTtransientthermalimpedanceasa functionofpulsewidth (D=tp/T) Datasheet V2.
IKFW5N6DH3E Zth(jh),TRANSIENTTHERMALIMPEDANCE[K/W].. D =.5. E7 E6 E5 E4... tp,pulsewidth[s].2..5.2. single pulse i: 2 3 4 5 6 ri[k/w]:.4264.769.32538.32296.36223.23287 τi[s]: 2.3E4.4E3.228.62.78857 5.9434 Figure 2. Diodetransientthermalimpedanceasa functionofpulsewidth (D=tp/T) trr,reverserecoverytime[ns] 25 2 5 5 Tvj = 25 C, IF = 2A Tvj = 75 C, IF = 2A 2 4 6 8 2 dif/dt,diodecurrentslope[a/µs] Figure 22. Typicalreverserecoverytimeasafunction ofdiodecurrentslope (VR=4V).4.2 Tvj = 25 C, IF = 2A Tvj = 75 C, IF = 2A 8 6 Tvj = 25 C, IF = 2A Tvj = 75 C, IF = 2A Qrr,REVERSERECOVERYCHARGE[µC]..8.6.4 Irr,REVERSERECOVERYCURRENT[A] 4 2 8 6 4.2 2. 2 4 6 8 2 dif/dt,diodecurrentslope[a/µs] Figure 23. Typicalreverserecoverychargeasa functionofdiodecurrentslope (VR=4V) 2 4 6 8 2 dif/dt,diodecurrentslope[a/µs] Figure 24. Typicalreverserecoverycurrentasa functionofdiodecurrentslope (VR=4V) Datasheet V2.
IKFW5N6DH3E TRENCHSTOPTM Advanced Isolation 2 Tvj = 25 C, IF = 2A Tvj = 75 C, IF = 2A Tvj = 25 C Tvj = 75 C 2 IF, FORWARD CURRENT [A] dirr/dt, DIODE PEAK RATE OF FALL OF Irr [A/µs] 3 4 5 6 8 6 4 7 2 8 9 2 4 6 8 2 dif/dt, DIODE CURRENT SLOPE [A/µs] 2 3 4 VF, FORWARD VOLTAGE [V] Figure 25. Typical diode peak rate of fall of reverse recovery current as a function of diode current slope (VR=4V) Figure 26. Typical diode forward current as a function of forward voltage 2. IF = A IF = 2A IF = 4A VF, FORWARD VOLTAGE [V].75.5.25. 25 5 75 25 5 75 Tj, JUNCTION TEMPERATURE [ C] Figure 27. Typical diode forward voltage as a function of junction temperature Datasheet 2 V 2.
IKFW5N6DH3E TRENCHSTOPTM Advanced Isolation PGTO2473AI (PG HSIP247 3) DIMENSIONS A A A2 A3 b c D D E E e L L øp øp Q Note: Datasheet MILLIMETERS MAX. 5.8 4.9 2.59.28.3.7 22.4 7.6.9 3.88 5.44 8.3 8.9 2.76 2.96 3.5 3.7 5.7 5.9 5.96 6.36 MIN. 4.7 2.23.2..5 22.2 6.96.7 3.68 DOCUMENT NO. Z8B86434 REVISION SCALE 3: 2 3 4 5 6 7 8mm EUROPEAN PROJECTION ISSUE DATE 8.8.27 For a proper handling and assembly of the advanced isolation device in the application the isolation layer must not be exposed to potential penetration via sharp implements or mechanical impacts/shocks, which exceed levels indicated in International Standard (IEC668 2 6 and IEC668 2 27). The advanced isolation device is intended only to be used assembled on an appropriate heatsink with recommended flatness of <2µm per mm and roughness of <µm. 3 V 2.
IKFW5N6DH3E TRENCHSTOPTM Advanced Isolation Testing Conditions VGE(t) I,V 9% VGE t rr = t a + t b Q rr = Q a + Q b dif/dt a % VGE b t Qa IC(t) Qb di 9% IC 9% IC % IC % IC Figure C. Definition of diode switching characteristics t VCE(t) t td(off) tf td(on) t tr Figure A. VGE(t) 9% VGE Figure D. % VGE t IC(t) CC 2% IC t Figure E. Dynamic test circuit Parasitic inductance Ls, parasitic capacitor Cs, relief capacitor Cr, (only for ZVT switching) VCE(t) t2 E off = t4 VCE x IC x dt E t t on = VCE x IC x d t 2% VCE t3 t2 t3 t4 t Figure B. Datasheet 4 V 2.
IKFW5N6DH3E TRENCHSTOPTM Advanced Isolation Revision History IKFW5N6DH3E Revision:, Rev. 2. Previous Revision Revision Date Subjects (major changes since last revision) 2. Final data sheet Datasheet 5 V 2.
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