MPLAD30KP160A/TR

Introduction

The MPLAD30KP160A/TR is a high-performance transient voltage suppressor (TVS) diode designed to protect sensitive electronic equipment from voltage transients induced by lightning and other transient voltage events. This entry provides an overview of the MPLAD30KP160A/TR, including its product category, basic information, specifications, pin configuration, functional features, advantages and disadvantages, working principles, application field plans, and alternative models.

Product Category

The MPLAD30KP160A/TR belongs to the TVS diode category, specifically designed for transient voltage protection in various electronic applications.

Basic Information Overview

• Use: The primary use of the MPLAD30KP160A/TR is to provide surge protection for sensitive electronic components against transient voltage events.
• Characteristics: It offers low clamping voltage, high surge capability, and fast response time, making it suitable for protecting a wide range of electronic devices.
• Package: The MPLAD30KP160A/TR is available in a compact, surface-mount package, ensuring ease of integration into circuit designs.
• Essence: Its essence lies in providing robust transient voltage suppression to safeguard electronic circuits from voltage spikes and surges.
• Packaging/Quantity: The diode is typically supplied in reels or tubes, with specific quantities per package depending on the manufacturer's specifications.

Specifications

• Peak Pulse Power: 30000 W
• Standoff Voltage: 160 V
• Breakdown Voltage: 178 V to 197 V
• Clamping Voltage: 259 V at 43 A
• Operating Temperature Range: -55°C to +175°C
• Storage Temperature Range: -55°C to +175°C

Detailed Pin Configuration

The MPLAD30KP160A/TR features a standard TVS diode pin configuration, with clear markings for anode and cathode connections. It is essential to adhere to the recommended layout guidelines for proper installation and functionality.

Functional Features

• Transient Voltage Suppression: Effectively clamps transient voltages to safe levels, protecting downstream components.
• Fast Response Time: Rapid reaction to transient events ensures minimal impact on the protected circuitry.
• High Surge Capability: Capable of withstanding high surge currents, enhancing overall system reliability.

Advantages and Disadvantages

Advantages

• High surge handling capability
• Low clamping voltage
• Compact surface-mount package
• Wide operating temperature range

Disadvantages

• Higher cost compared to standard diodes
• Requires careful layout and design considerations for optimal performance

Working Principles

The MPLAD30KP160A/TR operates based on the principle of avalanche breakdown, where it rapidly conducts excess current away from the protected circuit when subjected to transient voltage events. This prevents the voltage from reaching damaging levels and diverts the energy safely to ground.

Detailed Application Field Plans

The MPLAD30KP160A/TR finds extensive application in various industries, including: - Telecommunications - Industrial automation - Automotive electronics - Power supply systems - Consumer electronics

Its robust transient voltage suppression capabilities make it an ideal choice for protecting sensitive electronic equipment in these fields.

Detailed and Complete Alternative Models

• MPLAD30KP180A/TR: Similar TVS diode with a higher standoff voltage of 180 V
• MPLAD30KP130CA/TR: TVS diode with a lower standoff voltage of 130 V
• MPLAD30KP200A/TR: TVS diode with a higher standoff voltage of 200 V

These alternative models offer varying standoff voltages to cater to different application requirements while maintaining similar surge protection characteristics.

In conclusion, the MPLAD30KP160A/TR TVS diode serves as a reliable solution for transient voltage protection in diverse electronic applications, offering high surge capability, low clamping voltage, and fast response time. Its detailed specifications, pin configuration, functional features, advantages, and application field plans make it a valuable component in safeguarding electronic systems from transient voltage events.

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