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IRG4BC40W-SPBF
IGBT, 40 A, 2.5 V, 160 W, 600 V, TO-263 (D2PAK), 3 Pins
⚠️ Reference pricing provided. In case of supply shortages, we will connect you with our trusted procurement partners to ensure your project's continuity.
- Manufacturer: INFINEON
- Product type: Single IGBTs
- No. of Pins: 3Pins
- Power Dissipation: 160W
- Transistor Mounting: Surface Mount
- Transistor Case Style: TO-263 (D2PAK)
- Operating Temperature Max: 150°C
- Continuous Collector Current: 40A
- Collector Emitter Voltage Max: 600V
- Collector Emitter Saturation Voltage: 2.5V
| Delivery and price | |
|---|---|
| Units per pack | 1 |
| Price | 1.14 € |
| Current stock | 10+ |
| Lead time | 30 days |
Datasheet
## IRG4BC40WSPbF IRG4BC40WLPbF
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C<br>Vces = 600V<br>G VcE(on) typ. =<br>E @Vce = 15V, Ic =<br>n-channel<br>gS<br>—<br>S. NS"<br>D [2] Pak TO-262<br>IRG4BC40WSPbF IRG4BC40WLPbF<br>**----- End of picture text -----**<br>
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θ<br>Ric | dunctionto-CaseSSSCS~—~SC“‘“‘—C NCSC<br>θ<br>Ros | Case-to-Sink, Flat, Greased Surface =| SCS SS S~*d<br>θ<br>Rua | unetion-to-Ambient (PCB Mounted steady-state) = — «| —=S OS<br>we [2000] went<br>www.irf.com<br>**----- End of picture text -----**<br>
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∆ ∆<br>Perce [err otestr seston vote © 18 [= |v [ Vee=ov text<br>| — [2.05 | 25 | Ic = 20A Vor = 15V<br>Si<br>[Vee ∆ ∆ |— |190| — | lc = 20A , Ty = 150°C<br>[Vee | Gate Threshold Vottage | 3.0 | — | 60 |<br>=<br>100V.e=A_—*d<br>fe |Tu | TempeForwa r atud T r eansconductance®Coeff of Threshold Votage«|[—48 | 1328 || — | mVPC)S | VV o ze=Vec.lo=250WA =|<br>f= frromenercorcin Fe a) HissarVoe = OV, Voz = 600Vacre —<br>[ces | GaletoEmitier Leakage Current [— [= = |st00/[2500 nA [Voc=s20v<br>Switching Characteristics @ Ty = 25°C (unless otherwise specified)<br>|_| Parameter | Min, [Typ. IMax.| nits] Conditions<br>[Qg | Total Gate Charge (turn-on) | — | 98 | 147 | Ic =20A<br>Oye | Gate = Collector Charge turn-on) [— | 36 [4 | | Voe= tv<br>Fae | [Turn-OnDelayTime]<br>ft} «i [RiseTime—SS~—S—C—Cs] SST — | 27|,| | y= HVC<br>Ω<br>CC i<br>[Eon | TurmOn Switching Loss «| — [Ott | — |_| Energy losses include "ta<br>[Eon | Tum-Off Switching Loss _——*| — [0.23 |— | mJ | See Fig. 9,10, 14<br>ee<br>sen | Tur-On belay Time =f a5 fie 0<br>t [RiseTime | — | 8 | — Io = 20A, Voc = 480V<br>Ω<br>**----- End of picture text -----**<br>
Ω
≤ ≤
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50<br>For both: Triangular wave:<br>Duty cycle: 50%<br>TPN T = 125°CJ | | 1111 | | | 1 1<br>40 T = 90°Csink<br>PL T Gate drive as specified Le<br>Power Dissipation = 28W Clamp voltage:<br>eT< 30 LAMLLL U K 80% of rated S|<br>Square wave:<br>60% of rated<br>So 20 voltage d e be MNoeNATITce 5 ELI<br>P 10 e e JU L TELUISNOTETY TTT<br>Ideal diodes<br>0 WELL: eb A<br>0.1 SS 1 10 | irs 100 1000<br>f, Frequency (kHz)<br>**----- End of picture text -----**<br>
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1000<br>See eee=<br>T = 25 CJ °<br>a a a<br> 100<br>T = 150 CJ °<br>fF | wl | | |<br> 10 AL<br>| |<br>V = 15VGE<br> 1 p ep 80µs PULSE WIDTH<br>1.0 2.0 3.0 4.0 5.0<br>V , Collector-to-Emitter Voltage (V)CE<br>C<br>I , Collector-to-Emitter Current (A)<br>**----- End of picture text -----**<br>
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1000<br>pf<br>a ee ee ee ee<br> 100<br>T = 150 CJ °<br>4<br> 10 Li T = 25 CJ ° ee eee eeel<br>V = 50VCC<br>e e 5µs PULSE WIDTH<br> 1<br>5 7 9 11<br>V , Gate-to-Emitter Voltage (V)GE<br>C<br>I , Collector-to-Emitter Current (A)<br>**----- End of picture text -----**<br>
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50 3.0<br>V = 15VGE<br>80 us PULSE WIDTH<br>pif} tt tt P E<br>40 I = AC 40<br>2.5<br>SoS> ee _—— a<br>NE | EEE~~ o<br>30<br>COOERCCEP)) sera I = AC 20 t t<br>2.0<br>20 I = AC 10<br>pif = R R<br>tt IN a Se<br>tttSoeeceeett NS 1.5 PLLE L ee<br>10 PttTEtTTTIN<br>0 PT EET TTT rx 1.0 PPE EEE EEEEE<br>25 50 75 100 125 150 -60 -40 -20 0 20 40 60 80 100 120 140 160<br>T , Case Temperature ( C)C ° T , Junction Temperature ( C)J °<br>Fig. 4 - Maximum Collector Current vs. Case Fig. 5 - Typical Collector-to-Emitter Voltage<br>Temperature vs. Junction Temperature<br> 1 ==<br>eS ee ee east neil<br>D = 0.50<br>ce arate en es ee Ll<br>rr<br>e 0.20 A pwneea |<br>0.1 c 0.10 eeeeea Aeee|<br>eee O—oeaeZ e eee e ee PDM<br>p 0.050.02 SINGLE PULSE e ttt t1 t2<br>See 0.01 (THERMAL RESPONSE) ee Notes:<br>1. Duty factor D = t / t1 2<br>2. Peak TJ = PDM x Z thJC + TC<br>0.01 waeS TR TTIIl AIT<br>0.00001 alll 0.0001 A 0.001 ET 0.01 0.1 1<br>t , Rectangular Pulse Duration (sec)1<br>Maximum DC Collector Current(A) CE<br>V , Collector-to-Emitter Voltage(V)<br>thJC<br>Thermal Response (Z )<br>**----- End of picture text -----**<br>
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4000<br>VGE = 0V, f = 1MHz<br>Cies = Cge + Cgc , C SHORTEDce<br>Cres = Cgc<br>TT] Coes = Cce + Cgc<br>3000 \ |<br>P S Cies U TT<br>Naa Su t<br>2000<br>||<br>| alll<br>Coes x<br>1000<br>Cres<br>eS EE<br>P ~RLhoo<br>0<br> 1 10 100<br>V , Collector-to-Emitter Voltage (V)CE<br>Fig. 7 - Typical Capacitance vs.<br>Collector-to-Emitter Voltage<br>1.0<br>V = 480VCC<br>0.9 V = 15VT = 25 CJGE °<br>I = 20AC | | | | | PF<br>0.8 a rt CLAW<br>0.7<br>Poptea<br>Sa<br>0.6<br>a<br>4Aeeeeeee<br>0.5 TTATLLLT<br>0.40.3 2Yia {it eei ttttt<br>10 20 30 40 50 60<br>R , Gate Resistance (Ohm)G (Ω)<br>C, Capacitance (pF)<br>Total Switching Losses (mJ)<br>**----- End of picture text -----**<br>
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20<br>VCC = 400V<br>I C = 20A<br>P T<br>16<br>Pt; tT<br>HERA<br>12<br>Sane<br>PTT Ey<br>8<br>SERRE 4EeR<br>|jl— a |<br>4<br>ee<br>LtAREER| ytpy<br>0<br>0 20 40 60 80 100<br>Q , Total Gate Charge (nC)G<br>Fig. 8 - Typical Gate Charge vs.<br>Gate-to-Emitter Voltage<br> 10<br>R =G Ωhm<br>V = 15VGE<br>V = 480VCC SeGeGeeeee<br>Seeeeeeeeeee<br>Oa a ne a I = AC 40<br>|ilil| |ipases i<br> 1 I = A C 20<br>pee<br>SUnERM CARDED Pe ce Gatine<br>POPE eamass I = AC 10<br>ONBSFan oeBERRDS<n<br>Tt peer<br>IterpiaerTililililil<br>0.1<br>-60 -40 -20 0 20 40 60 80 100 120 140 160<br>T , Junction Temperature ( C )J °<br>GE<br>V , Gate-to-Emitter Voltage (V)<br>Total Switching Losses (mJ)<br>**----- End of picture text -----**<br>
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2.0 1000<br>R =G ΩOhm V = 20VGE<br>T = 150 CJ ° T = 125 CJ o<br>V = 480VCC<br>V = 15VGE<br>1.5<br>A | ll<br>a ee<br>1.0 EanPt 4eee 100 AoT<br>0.5 TT TyMTT TTLL ae 7 em<br>L aeeeee<br>Pry TPT fy eT<br>SAFE OPERATING AREA<br>0.0 PTE Err 10 | |<br>5 15 25 35 45 1 10 100 1000<br>I , Collector-to-emitter Current (A)C V , Collector-to-Emitter Voltage (V)CE<br>Total Switching Losses (mJ)<br>C<br>I , Collector-to-Emitter Current (A)<br>**----- End of picture text -----**<br>
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RL = VCCICM<br>L D.U.T.<br>V *<br>C<br>50V<br>1000V 480µF<br>0 - VCC<br>(0)<br>HTT fe if<br>* Driver same type as D.U.T.; Vc = 80% of Vce(max)<br>* Note: Due to the 50V power supply, pulse width and inductor Pulsed Collector Current<br> will increase to obtain rated Id.<br>Test Circuit<br>Fig. 13a - Clamped Inductive Fig. 13b - Pulsed Collector<br>Load Test Circuit Current Test Circuit<br>IC<br>000 NN<br>L<br>Driver* D.U.T.<br>VC<br>50V<br>1000V<br>T (IE) Ch Fig. 14aTest - Sw C rcuit i tching<br>® * Driver same type<br>as D.U.T., VC =<br>(©)<br>JJ \<br>90%<br>10%<br>eens<br>VC<br>90%<br>i of: a a td(off) 2 Fig. 14bWaveforms-<br>IC 5%10%<br>tr tf<br>t d(on) t=5µs<br>Eon Eoff<br>E = (E +E )ts on off<br>**----- End of picture text -----**<br>
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## Dimensions are shown in millimeters (inches)
OR ~~—~~ For the most 8
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## TO-262 Package Outline Dimensions are shown in millimeters (inches)
## TO-262 Part Marking Information
## OR
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Dimensions are shown in millimeters (inches)
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TRR<br>1.60 (.063)<br>1.50 (.059)<br>1.60 (.063)<br>4.10 (.161)<br>3.90 (.153) 1.50 (.059) 0.368 (.0145)<br>0.342 (.0135)<br>fed |<br>FEED DIRECTION 1.85 (.073) 1 11.60 (.457)<br>1.65 (.065) 11.40 (.449) 24.30 (.957)<br>O49 O64 =| 15.42 (.609) |<br>23.90 (.941)<br>15.22 (.601)<br>TRL<br>1.75 (.069)<br>10.90 (.429) 1.25 (.049)<br>10.70 (.421) 4.72 (.136)<br>0000 a 16.10 (.634) J sj 4.52 (.178)<br>15.90 (.626)<br>FEED DIRECTION<br>13.50 (.532) 27.40 (1.079)<br>12.80 (.504) 23.90 (.941) 1<br>4<br>330.00 60.00 (2.362)<br>(14.173) MIN.<br> MAX.<br>| oO |<br>30.40 (1.197)<br>NOTES : OO | \L MAX.<br>1. COMFORMS TO EIA-418.2. CONTROLLING DIMENSION: MILLIMETER. 26.40 (1.039)24.40 (.961) IL 4<br>3. DIMENSION MEASURED @ HUB.<br>3<br>**----- End of picture text -----**<br>
4. INCLUDES FLANGE DISTORTION @ OUTER EDGE.
**IR WORLD HEADQUARTERS:** 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105
TAC Fax: (310) 252-7903 Visit us at www.irf.com for sales contact information **.** 02/2010
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Updated at February 9, 2023
Infineon Technologies is a globally recognized leader in semiconductor solutions, renowned for driving innovation in power management, energy efficiency, and modern mobility. With a strong legacy of engineering excellence, the company provides highly reliable components designed to meet the rigorous demands of industrial, automotive, and advanced commercial applications. The core of our Infineon portfolio is centered on their industry-leading discrete semiconductors. We offer an extensive selection of single and dual MOSFETs, alongside a robust range of single IGBTs and advanced IGBT modules. These flagship power transistors are essential for high-efficiency power conversion and motor control, providing engineers with superior thermal performance and minimized switching losses. Beyond advanced field-effect transistors, the selection includes a comprehensive array of diodes and rectifiers, heavily featuring Schottky diodes, as well as fast-recovery and RF/PIN diodes. This power foundation is further supported by bipolar transistors, intelligent power modules, and thyristor SCR modules, delivering the critical building blocks required for complex power system designs. To support broader system integration, the portfolio also encompasses specialized solutions such as solid-state relays, AC/DC LED driver ICs, and Bluetooth communications modules. From high-power industrial rectifiers to wireless connectivity adapters, Infineon equips designers with the precision components needed to build efficient, scalable, and fully connected electronic systems.
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