Specification	R6535KNZ4C13

Current - Continuous Drain (Id) @ 25°C	35 A
Drain to Source Voltage (Vdss)	650 V
Drive Voltage (Max Rds On, Min Rds On)	10 V
FET Type	N-Channel
Gate Charge (Qg) (Max) @ Vgs	72 nC
Mounting Type	Through Hole
Operating Temperature	150 °C
Package / Case	TO-247-3
Power Dissipation (Max)	379 W
Rds On (Max) @ Id, Vgs	115 mOhm
Supplier Device Package	TO-247G
Technology	MOSFET (Metal Oxide)
Vgs (Max)	20 V
Vgs(th) (Max) @ Id	5 V

R6535 Series

650V 35A TO-247, High-speed switching Power MOSFET

Part	Drive Voltage (Max Rds On, Min Rds On)	Vgs (Max)	Power Dissipation (Max)	Gate Charge (Qg) (Max) @ Vgs	Mounting Type	Technology	Input Capacitance (Ciss) (Max) @ Vds [Max]	Package / Case	Supplier Device Package	Operating Temperature	FET Type	Vgs(th) (Max) @ Id	Current - Continuous Drain (Id) @ 25°C	Drain to Source Voltage (Vdss)	Rds On (Max) @ Id, Vgs
Rohm Semiconductor R6535ENZ4C13	10 V	20 V	379 W	110 nC	Through Hole	MOSFET (Metal Oxide)	2600 pF	TO-247-3	TO-247G	150 °C	N-Channel	4 V	35 A	650 V	115 mOhm
Rohm Semiconductor R6535KNZ4C13	10 V	20 V	379 W	72 nC	Through Hole	MOSFET (Metal Oxide)		TO-247-3	TO-247G	150 °C	N-Channel	5 V	35 A	650 V	115 mOhm

Pricing

Prices provided here are for design reference only. For realtime values and availability, please visit the distributors directly

Distributor	Package	Quantity	$

Digikey	N/A	248	$ 4.57
	Tube	1	$ 3.25
		30	$ 1.81
		120	$ 1.63
Newark	Each	1	$ 7.60
		10	$ 7.16
		25	$ 6.77

Description

General part information

R6535 Series

The R6xxxKNx series are high-speed switching products, Super Junction MOSFETs, that place an emphasis on high efficiency. This series products achieve higher efficiency via high-speed switching. High-speed switching makes it possible to contribute to higher efficiency in PFC and LLC circuits.

Documents

Technical documentation and resources

R6535KNZ4C13

Deep-Dive with AI

R6535KNZ4C13

Deep-Dive with AI

Technical Specifications

R6535 Series

Pricing

Description

R6535 Series

Documents

Technical Data Sheet EN

Basics of Thermal Resistance and Heat Dissipation

Compliance of the RoHS directive

Example of Heat Dissipation Design for TO Packages: Effect of Heat Dissipation Materials

Overview of ROHM's Simulation Models(for ICs and Discrete Semiconductors)

Measurement Method and Usage of Thermal Resistance RthJC

Power Eco Family: Overview of ROHM's Power Semiconductor Lineup

Report of SVHC under REACH Regulation

List of Transistor Package Thermal Resistance

Temperature derating method for Safe Operating Area (SOA)

Part Explanation

Precautions When Measuring the Rear of the Package with a Thermocouple

Calculation of Power Dissipation in Switching Circuit

R6535KNZ4 ESD Data

Types and Features of Transistors

Method for Calculating Junction Temperature from Transient Thermal Resistance Data

Method for Monitoring Switching Waveform

TO247AD Explanation for Marking

Notes for Calculating Power Consumption:Static Operation

How to Use LTspice&reg; Models: Tips for Improving Convergence

Notes for Temperature Measurement Using Forward Voltage of PN Junction

θ<sub>JA</sub> and Ψ<sub>JT</sub>

About Flammability of Materials

PCB Layout Thermal Design Guide

About Export Regulations

How to Use LTspice&reg; Models

What Is Thermal Design

How to Use the Thermal Resistance and Thermal Characteristics Parameters

Anti-Whisker formation - Transistors

MOSFET Gate Drive Current Setting for Motor Driving

Judgment Criteria of Thermal Evaluation

Moisture Sensitivity Level - Transistors

What is a Thermal Model? (Transistor)

Two-Resistor Model for Thermal Simulation

Impedance Characteristics of Bypass Capacitor

Package Dimensions

θ<sub>JC</sub> and Ψ<sub>JT</sub>

Notes for Temperature Measurement Using Thermocouples

MOSFET Gate Resistor Setting for Motor Driving

Importance of Probe Calibration When Measuring Power: Deskew

R6535 Series

How to Use LTspice® Models: Tips for Improving Convergence

How to Use LTspice® Models