VUO125-16NO7

Bridge Rectifier, Three Phase, 1.6 kV, 150 A, PWS-C, 5 Pins, 1.34 V

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Manufacturer: IXYS SEMICONDUCTOR
Product type: Bridge Rectifier Diodes
No. of Phases:Three Phase; Repetitive Reverse Voltage Vrrm Max:1.6kV; Forward Current If(AV):150A; Bridge Rectifier Case Style:PWS-C; Forward Voltage VF Max:1.34V; No. of Pins:5Pin
SVHC: Lead (17-Jan-2023)
No. of Pins: 5Pins
No. of Phases: Three Phase
Product Range: -
Forward Voltage Max: 1.34V
Forward Surge Current: 1.8kA
Average Forward Current: 150A
Bridge Rectifier Mounting: Panel Mount
Operating Temperature Max: 150°C
Bridge Rectifier Case Style: PWS-C
Repetitive Peak Reverse Voltage: 1.6kV

Delivery and price
Units per pack	10
Price	47.68 €
Current stock	10+
Lead time	30 days

Datasheet

## **VUO125-16NO7** 

## **Standard Rectifier Module** 

|||**3~**||
|---|---|---|---|
||**Rectifier**|||
|RRM<br>V||1600<br>=|V|
|I|DAV|150<br>=|A|
|I|FSM|1800<br>=|A|



## 3~ Rectifier Bridge 

## **Part number** 

## **VUO125-16NO7** 

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+<br>D1 D3 D5<br>~<br>~<br>~<br>D2 D4 D6<br>-<br>**----- End of picture text -----**<br>


## **Features / Advantages:** 

- Package with DCB ceramic 

- Improved temperature and power cycling 

- Planar passivated chips 

- Very low forward voltage drop 

- Very low leakage current 

## **Applications:** 

- Diode for main rectification 

- For three phase bridge configurations 

- Supplies for DC power equipment 

- Input rectifiers for PWM inverter 

- Battery DC power supplies 

- Field supply for DC motors 

## PWS-C 

## **Package:** 

- Isolation Voltage:          V~3000 

- Industry standard outline 

- RoHS compliant 

- Easy to mount with two screws 

- Base plate: Copper internally DCB isolated 

- Advanced power cycling 

## **Disclaimer Notice** 

Information furnished is believed to be accurate and reliable. However, users should independently evaluate the suitability of and test each product selected for their own applications. Littelfuse products are not designed for, and may not be used in, all applications. Read complete Disclaimer Notice at www.littelfuse.com/disclaimer-electronics. 

IXYS reserves the right to change limits, conditions and dimensions. 

Data according to IEC 60747and per semiconductor unless otherwise specified 

20191220b 

© 2019 IXYS all rights reserved 

**VUO125-16NO7** 

|**Ratings**<br>**Rectifier**|**Ratings**<br>**Rectifier**|**Ratings**<br>**Rectifier**|**Ratings**<br>**Rectifier**|**Ratings**<br>**Rectifier**|**Ratings**<br>**Rectifier**|
|---|---|---|---|---|---|
|**Symbol**<br>**Definition**<br>**Conditions**||**min.**|**typ.**|**max.**|**Unit**|
|**VRSM**<br>_max. non-repetitive reverse blocking voltage_<br>T    =   25°C<br>VJ||||1700|V|
|**VRRM**<br>_max. repetitive reverse blocking voltage_<br>T    =   25°C<br>VJ||||1600|V|
|**IR**<br>_reverse current_|V    =          V<br>R<br>T    =   25°C<br>VJ<br>T    =       °C<br>VJ<br>V    =          V<br>R<br>1600<br>150<br>1600|||200<br>2|mA<br>µA|
|**VF**<br>_forward voltage drop_|T    =   25°C<br>VJ<br>I  =          A<br>F<br>50<br>I  =          A<br>F<br>150|||1.07<br>1.34|V<br>V|
||T    =       °C<br>VJ<br>I  =          A<br>F<br>50<br>I  =          A<br>F<br>150<br>125|||0.97<br>1.31|V<br>V|
|**I**<br>**DAV**<br>_bridge output current_|T  =       °C<br>C<br>110<br>T    =       °C<br>VJ<br>150<br>d =<br>rectangular<br>⅓|||150|A|
|**VF0**<br>T    =       °C<br>VJ<br>150<br>**rF**<br>_threshold voltage_<br>_slope resistance_<br>_for power loss calculation only_||||0.76<br>3.6|V<br>mΩ|
|**R**<br>_thermal resistance junction to case_<br>**thJC**||||0.6|K/W|
|**R**<br>_thermal resistance case to heatsink_<br>**thCH**|||0.3||K/W|
|**Ptot**<br>_total power dissipation_|T    =   25°C<br>C|||205|W|
|**IFSM**<br>_max. forward surge current_|t =  10 ms; (50 Hz), sine<br>T    =   45°C<br>VJ<br>V    = 0 V<br>R<br>t = 8,3 ms; (60 Hz), sine|||1.80<br>1.95|kA<br>kA|
||T    =       °C<br>VJ<br>150<br>V    = 0 V<br>R<br>t =  10 ms; (50 Hz), sine<br>t = 8,3 ms; (60 Hz), sine|||1.53<br>1.65|kA<br>kA|
|**I²t**<br>_value for fusing_|T    =   45°C<br>V    = 0 V<br>t =  10 ms; (50 Hz), sine<br>t = 8,3 ms; (60 Hz), sine<br>VJ<br>R|||16.2<br>15.7|kA²s<br>kA²s|
||T    =       °C<br>150<br>V    = 0 V<br>t =  10 ms; (50 Hz), sine<br>t = 8,3 ms; (60 Hz), sine<br>VJ<br>R|||11.7<br>11.3|kA²s<br>kA²s|
|**CJ**<br>_junction capacitance_|V  =          V;<br>400<br>T    =   25°C<br>f = 1 MHz<br>R<br>VJ||58||pF|



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IXYS reserves the right to change limits, conditions and dimensions. 

Data according to IEC 60747and per semiconductor unless otherwise specified 

20191220b 

© 2019 IXYS all rights reserved 

**VUO125-16NO7** 

|**Symbol**<br>**Definition**<br>**Conditions**|**min.**|**typ.**|**max.**|**Unit**|
|---|---|---|---|---|
|**I RMS**<br>_RMS current_<br>per terminal<br>~~——~~|~~——~~|~~——~~|150|A|
|**TVJ**<br>_virtual junction temperature_<br>~~——~~<br>~~T=~~|-40<br>~~——~~<br>~~T=~~|~~——~~<br>~~T=~~|150|°C|
|**Top**<br>_operation temperature_<br>~~T=~~<br>~~>~~|-40<br>~~T=~~<br>~~>~~|~~T=~~<br>~~>~~|125|°C|
|**Tstg**<br>_storage temperature_<br>~~>~~|-40<br>~~>~~|~~>~~|125|°C|
|**Weight**||250||g|
|**M D**<br>_mounting torque_<br>**M T**<br>_terminal torque_<br>~~|~~|4.25<br>4.25<br>~~|~~|~~|~~|5.75<br>5.75|Nm<br>Nm|
|**dSpp/App**<br>_creepage distance on surface | striking distance through air_<br>**dSpb/Apb**<br>_terminal to backside_<br>_terminal to terminal_<br>~~|~~|26.0<br>14.0<br>~~|~~|~~|~~||mm<br>mm|
|**V**<br>t = 1 second<br>t = 1 minute<br>_isolation voltage_<br>50/60 Hz, RMS; I≤1 mA<br>ISOL<br>**ISOL**|3000<br>2500|||V<br>V|



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Logo<br>Circuit<br>UL<br>Diagram<br>Product<br>Number [_ ealee XXXX-XXXX yywwZ 1234<br>Date Code Location Lot#<br>Ordering Ordering Number Marking on Product Delivery Mode Quantity Code No.<br>ee Standard VUO125-16NO7 VUO125-16NO7 Box 10 456780<br>**----- End of picture text -----**<br>


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 Equivalent Circuits for Simulation * on die level T    =VJ 150°C<br>I V0 R 0 Rectifier<br>~Co<br>V 0 max threshold voltage 0.76 V<br>R0 max slope resistance * 2.4 mΩ<br>**----- End of picture text -----**<br>


IXYS reserves the right to change limits, conditions and dimensions. 

Data according to IEC 60747and per semiconductor unless otherwise specified 

20191220b 

© 2019 IXYS all rights reserved 

**VUO125-16NO7** 

## **Outlines PWS-C** 

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1<br>67<br>9<br>20 13.5<br>10<br>M5<br>50 8.5<br>+<br>D1 D3 D5<br>~<br>~<br>~<br>D2 D4 D6<br>-<br>2<br>29 31<br>27.5<br>6.5<br>1.5<br>11<br>10 5.5 28 50<br>10.6<br>**----- End of picture text -----**<br>


IXYS reserves the right to change limits, conditions and dimensions. 

Data according to IEC 60747and per semiconductor unless otherwise specified 

20191220b 

© 2019 IXYS all rights reserved 

**VUO125-16NO7** 

## **Rectifier** 

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**----- Start of picture text -----**<br>
200 18000<br>1400 50 Hz0.8 x V RRM VR = 0 V<br>160 15000<br>I [2] t<br>1200<br>IF 120 TVJ = 45°C 12000<br>[A] IFSM [A [2] s] TVJ = 45°C<br>80 9000<br>1000<br>125°C T VJ  = [A] TVJ = 150°C TVJ = 150°C<br>40 150°C 6000<br>800<br>TVJ = 25°C<br>0 3000<br>0.4 0.8 1.2 1.6 10 [-3] 10 [-2] 10 [-1] 10 [0] 1 10<br>VF [V] t [s] t [ms]<br>Fig. 1 Forward current versus Fig. 2 Surge overload current Fig. 3 I [2] t versus time per diode<br>voltage drop per diode vs. time per diode<br>70 200<br>DC = R thJA : DC =<br>60 1 0.2 KW 1<br>0.5 0.4 KW 160 0.5<br>50 0.330.4 00..68 KWKW IF(AV)M 0.4<br>0.17 0.33<br>1.0 KW 120<br>Ptot 40 0.08 2.0 KW [A] 0.17<br>0.08<br>30<br>[W] 80<br>20<br>40<br>10<br>0 0<br>0 10 20 30 40 50 60 0 25 50 75 100 125 150 0 25 50 75 100 125 150<br>IF(AV)M [A] TA  [°C] TC [°C]<br>Fig. 4 Power dissipation vs. forward current Fig. 5 Max. forward current vs.<br>and ambient temperature per diode case temperature per diode<br>0.6<br>Constants for ZthJC calculation:<br>i Rth (K/W) ti (s)<br>0.4<br>1 0.060 0.020<br>ZthJC 2 0.003 0.010<br>[K/W]<br>3 0.150 0.225<br>0.2<br>4 0.243 0.800<br>5 0.144 0.580<br>0.0<br>1 10 100 1000 10000<br>t [ms]<br>Fig. 6 Transient thermal impedance junction to case vs. time per diode<br>**----- End of picture text -----**<br>


IXYS reserves the right to change limits, conditions and dimensions. 

Data according to IEC 60747and per semiconductor unless otherwise specified 

20191220b 

© 2019 IXYS all rights reserved

Updated at June 4, 2026

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