MXP4KE130CA Product Overview

Introduction

The MXP4KE130CA belongs to the category of high-power transient voltage suppressor (TVS) diodes. These diodes are designed to protect sensitive electronics from voltage spikes and transients.

Basic Information Overview

Category: High-power transient voltage suppressor diode
Use: Protection against voltage spikes and transients
Characteristics: High power dissipation, low clamping voltage, fast response time
Package: Axial leaded
Essence: Safeguarding electronic circuits from voltage surges
Packaging/Quantity: Available in reels or bulk packaging, quantity varies by manufacturer

Specifications

Peak Power Dissipation: 4000W
Breakdown Voltage: 130V
Clamping Voltage: 177V
Operating Temperature Range: -55°C to +175°C
Storage Temperature Range: -55°C to +175°C

Detailed Pin Configuration

The MXP4KE130CA TVS diode has an axial leaded package with two leads. The pin configuration is as follows: - Pin 1: Anode - Pin 2: Cathode

Functional Features

Transient Voltage Suppression: Provides rapid response to voltage spikes, diverting excess current away from sensitive components.
High Power Dissipation: Capable of handling large transient currents without degradation.
Low Clamping Voltage: Limits the voltage across the protected circuit during a transient event.

Advantages and Disadvantages

Advantages

Effective protection against voltage transients
High power dissipation capability
Fast response time

Disadvantages

Higher cost compared to lower power TVS diodes
Larger physical size due to higher power handling capacity

Working Principles

The MXP4KE130CA TVS diode operates based on the principle of avalanche breakdown. When a voltage surge occurs, the diode rapidly conducts, shunting the excess current to ground and limiting the voltage across the protected circuit.

Detailed Application Field Plans

The MXP4KE130CA is commonly used in various applications including: - Power supply units - Automotive electronics - Industrial control systems - Telecommunication equipment - Consumer electronics

Detailed and Complete Alternative Models

Some alternative models to the MXP4KE130CA TVS diode include: - P6KE130CA - 1.5KE130CA - SA15CA

In summary, the MXP4KE130CA TVS diode offers robust transient voltage suppression capabilities, making it an essential component for protecting sensitive electronic circuits from voltage spikes and transients.

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技術ソリューションにおける MXP4KE130CA の適用に関連する 10 件の一般的な質問と回答をリストします。

What is MXP4KE130CA?
- MXP4KE130CA is a type of transient voltage suppressor diode used to protect electronic circuits from overvoltage transients.
What is the maximum peak pulse power dissipation of MXP4KE130CA?
- The maximum peak pulse power dissipation of MXP4KE130CA is typically 400 watts.
What is the breakdown voltage of MXP4KE130CA?
- The breakdown voltage of MXP4KE130CA is 130 volts.
What are the typical applications of MXP4KE130CA?
- MXP4KE130CA is commonly used in surge protection for sensitive electronics, such as in telecommunications equipment, industrial control systems, and automotive electronics.
What is the operating temperature range of MXP4KE130CA?
- The operating temperature range of MXP4KE130CA is typically -55°C to +175°C.
What is the response time of MXP4KE130CA?
- The response time of MXP4KE130CA is very fast, typically in the nanosecond range.
What is the packaging type of MXP4KE130CA?
- MXP4KE130CA is commonly available in a DO-41 package.
What standards does MXP4KE130CA comply with?
- MXP4KE130CA typically complies with industry standards such as AEC-Q101 for automotive applications and RoHS for environmental compliance.
What are the key features of MXP4KE130CA?
- Key features of MXP4KE130CA include high surge capability, low clamping voltage, and fast response time.
How should MXP4KE130CA be integrated into a circuit for optimal performance?
- MXP4KE130CA should be placed in parallel with the circuit to be protected, ensuring that it can quickly divert excess voltage away from sensitive components. Additionally, proper PCB layout and grounding techniques should be followed for effective integration.