V130LA1 - Product Overview and Specifications

Introduction

The V130LA1 is a versatile electronic component that belongs to the category of metal oxide varistors (MOVs). This entry provides an in-depth overview of the V130LA1, including its basic information, specifications, pin configuration, functional features, advantages and disadvantages, working principles, application field plans, and alternative models.

Basic Information Overview

Category: Metal Oxide Varistor (MOV)
Use: Surge protection in electronic circuits
Characteristics: High energy absorption capability, fast response time
Package: Disc shape
Essence: Voltage clamping device for transient overvoltage protection
Packaging/Quantity: Typically available in bulk packaging

Specifications

Voltage Rating: 130V
Peak Current Capability: 4500A
Energy Absorption: 65J
Operating Temperature Range: -40°C to 85°C
Lead Material: Tin-plated copper

Detailed Pin Configuration

The V130LA1 typically has two leads for connection. The pin configuration is as follows: - Pin 1: Anode - Pin 2: Cathode

Functional Features

Surge Protection: Provides reliable protection against transient overvoltages.
Fast Response Time: Reacts quickly to voltage spikes, safeguarding sensitive electronic components.

Advantages and Disadvantages

Advantages

High energy absorption capability
Fast response time
Reliable surge protection for electronic circuits

Disadvantages

Limited to specific voltage ratings
May degrade over time with repeated surges

Working Principles

The V130LA1 operates based on the principle of voltage clamping. When a transient overvoltage occurs, the varistor rapidly changes its resistance, diverting excess current away from the protected circuit.

Detailed Application Field Plans

The V130LA1 finds extensive use in various applications, including: - Power supply units - Telecommunication equipment - Industrial control systems - Consumer electronics

Detailed and Complete Alternative Models

Some alternative models to the V130LA1 include: - V150LA20A - V140LA10A - V120LA5

In conclusion, the V130LA1 serves as a crucial component in safeguarding electronic circuits from transient overvoltages, offering high energy absorption and fast response times. Its application spans across diverse industries, making it an essential element in modern electronic designs.

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技術ソリューションにおける V130LA1 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 V130LA1?
- V130LA1 is a metal oxide varistor (MOV) component used for transient voltage surge suppression in electronic circuits.
Where can V130LA1 be used?
- V130LA1 can be used in various applications such as power supplies, industrial equipment, telecommunications, and consumer electronics.
What is the maximum voltage rating of V130LA1?
- The maximum voltage rating of V130LA1 is 130V.
How does V130LA1 provide surge protection?
- V130LA1 clamps excessive voltage levels by diverting surge currents away from sensitive components, thereby protecting them from damage.
What are the key specifications of V130LA1?
- The key specifications include peak current capability, energy absorption capacity, response time, and operating temperature range.
Can V130LA1 be used in outdoor applications?
- Yes, V130LA1 is suitable for outdoor applications as it is designed to withstand environmental conditions and temperature variations.
Is V130LA1 RoHS compliant?
- Yes, V130LA1 is compliant with the Restriction of Hazardous Substances (RoHS) directive, ensuring its environmental safety.
What are the recommended mounting and soldering techniques for V130LA1?
- V130LA1 can be mounted using appropriate PCB layout practices and soldered using reflow or wave soldering methods as per the manufacturer's guidelines.
Are there any application notes or design guidelines available for using V130LA1?
- Yes, the manufacturer provides application notes and design guidelines to assist in the proper integration of V130LA1 into technical solutions.
What are the potential failure modes of V130LA1 and how can they be mitigated?
- Potential failure modes include thermal runaway and degradation over time. These can be mitigated by proper derating, thermal management, and periodic testing of the varistors in the circuit.