onsemi QFET N-Channel MOSFET, 9.5 A, 200 V, 3-Pin TO-220F FQPF10N20C

Subtotal (1 tube of 50 units)*

£31.85

(exc. VAT)

£38.20

(inc. VAT)

Add to Basket
Select or type quantity
Last RS stock
  • Final 250 unit(s), ready to ship
Units
Per unit
Per Tube*
50 +£0.637£31.85

*price indicative

RS Stock No.:
145-4532
Mfr. Part No.:
FQPF10N20C
Brand:
onsemi
Find similar products by selecting one or more attributes.
Select all

Brand

onsemi

Channel Type

N

Maximum Continuous Drain Current

9.5 A

Maximum Drain Source Voltage

200 V

Package Type

TO-220F

Series

QFET

Mounting Type

Through Hole

Pin Count

3

Maximum Drain Source Resistance

360 mΩ

Channel Mode

Enhancement

Minimum Gate Threshold Voltage

2V

Maximum Power Dissipation

38 W

Transistor Configuration

Single

Maximum Gate Source Voltage

-30 V, +30 V

Width

4.7mm

Number of Elements per Chip

1

Maximum Operating Temperature

+150 °C

Transistor Material

Si

Length

10.16mm

Typical Gate Charge @ Vgs

20 nC @ 10 V

Height

9.19mm

Minimum Operating Temperature

-55 °C

QFET® N-Channel MOSFET, 6A to 10.9A, Fairchild Semiconductor


Fairchild Semiconductor’s new QFET® planar MOSFETs use advanced, proprietary technology to offer best-in-class operating performance for a wide range of applications, including power supplies, PFC (Power Factor Correction), DC-DC Converters, Plasma Display Panels (PDP), lighting ballasts, and motion control.
They offer reduced on-state loss by lowering on-resistance (RDS(on)), and reduced switching loss by lowering gate charge (Qg) and output capacitance (Coss). By using advanced QFET® process technology, Fairchild can offer an improved figure of merit (FOM) over competing planar MOSFET devices.


MOSFET Transistors, ON Semi


ON Semi offers a substantial portfolio of MOSFET devices that includes high-voltage (>250V) and low-voltage (<250V) types. The advanced silicon technology provides smaller die sizes, which it is incorporated into multiple industry-standard and thermally-enhanced packages.
ON Semi MOSFETs provide superior design reliability from reduced voltage spikes and overshoot, to lower junction capacitance and reverse recovery charge, to elimination of additional external components to keep systems up and running longer.

Related links