Surge withstand capability of metal oxide varistors for 10/350 µ s waveform

2011 International Symposium on Lightning Protection Pub Date : 2011-12-01 DOI:10.1109/SIPDA.2011.6088452

N. Tsukamoto

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引用次数: 3

Abstract

Lightning protection using surge protective devices (SPDs) have an important role for reliability of power delivery in current advanced information technology society. SPDs are categorized by 3 test class (Class I, II and III) according to IEC 61643-11) [1]. Especially, because class I SPDs intend to install at the entrance of power line according to IEC 61643-12) [2], it is important how big current SPD withstands. As components of SPD in Low voltage power distribution system, metal oxide varistors (MOVs) and/or spark gaps (GDT) were mainly used. SPDs with MOVs are voltage limiting type and have some merits as follows compared to that with GDT. • Capability of cut off the follow current • Lower residual voltage • Quickly response However, from surge withstand capability of the view, it is easy for MOVs to degrade its electrical characteristics by surge current because it translates from surge energy to heat itself. This point is a drawback for MOVs. This study describes the degradation mechanism of MOVs by surge impulses and the approaches for high and stable surge withstand capability through 10/350us impulse test results.

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10/350µs波形下金属氧化物压敏电阻抗浪涌能力

在当今信息技术发达的社会，采用电涌保护装置进行防雷对保证电力输送的可靠性起着重要的作用。根据IEC 61643-11标准，spd分为三类(I类、II类和III类)[1]。特别是，由于I类SPD按照IEC 61643-12[2]的要求安装在电力线的入口处，因此SPD能承受多大的电流非常重要。在低压配电系统中，主要采用金属氧化物压敏电阻(MOVs)和/或火花间隙(GDT)作为防雷元件。带有MOVs的spd是限压型，与GDT相比具有以下优点。然而，从浪涌承受能力的角度来看，由于浪涌能量本身转化为热量，MOVs很容易因浪涌电流而降低其电气特性。这是移动的一个缺点。本研究通过10/350us冲击试验结果，阐述了动臂受浪涌冲击的退化机理，以及获得高稳定浪涌抗冲击能力的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2011 International Symposium on Lightning Protection

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