Statistical analysis of voltage from constriction to micro-arc values during aging by fretting

2015 IEEE 61st Holm Conference on Electrical Contacts (Holm) Pub Date : 2015-10-01 DOI:10.1109/HOLM.2015.7355113

S. El Mossouess, Elsa Yee Kin Choi, N. Benjemâa, R. El Abdi, L. Doublet, T. Rodari, E. Carvou

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Abstract

In a previous work we observe that the vibration of contact interfaces is the main cause of contact voltage fluctuations due to the so called fretting corrosion phenomenon. In fact the process of generated particles by mechanical wear produce the increase of contact voltage frequently assimilated as high contact resistance. The main objective of this work is to examine conjointly contact voltage and the occurrence of arcs during the well-known three successive fretting phases. The arc voltage is measured during fretting with set oscilloscopes which plot the arc voltage histograms in real time. So, a histogram is built and arc duration is determined and the position on the track of fretting. We applied a voltage of 16V and a current of 3A. Samples extracted from commercial contact are used and fixed on vibration system (frequency 20Hz and relative displacement of 0.8 mm). The main results show that the arcs are observed during the first and final phase of fretting. We assume that after the initiation period of fretting, the wear is increased and induce the increase of the contact voltage and it reaches few hundred millivolts (melting and fritting voltage) and induce micro-arcs. In the second phase, it seems that number of arcs decreases. Finally in ultimate stage of degradation, intermittent arcing voltage is detected close 12V due to bounce on degraded surface filed wear debris.

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微动老化过程中电压从收缩到微弧值的统计分析

在以前的工作中，我们观察到由于所谓的微动腐蚀现象，接触界面的振动是接触电压波动的主要原因。实际上，机械磨损产生颗粒的过程产生接触电压的增加，通常被同化为高接触电阻。这项工作的主要目的是检查在众所周知的三个连续微动阶段中接触电压和电弧的发生。在微动过程中，用设置好的示波器测量电弧电压，示波器实时绘制电弧电压直方图。因此，建立了直方图，并确定了弧的持续时间和在微动轨迹上的位置。我们施加了16V的电压和3A的电流。采用商业接触面提取的试样，固定在振动系统上(频率20Hz，相对位移0.8 mm)。主要结果表明，在微动的第一阶段和最后阶段都观察到电弧。假设微动起始期后，磨损增大，接触电压升高，达到几百毫伏(熔化和摩擦电压)，产生微弧。在第二阶段，弧的数量似乎减少了。最后，在退化的最终阶段，由于退化表面的弹跳，检测到接近12V的间歇性电弧电压。

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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2015 IEEE 61st Holm Conference on Electrical Contacts (Holm)

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