Time and Level Analysis of Contact Voltage Intermittences Induced by Fretting in Power Connector

Electrical Contacts - 2007 Proceedings of the 53rd IEEE Holm Conference on Electrical Contacts Pub Date : 2007-09-24 DOI:10.1109/HOLM.2007.4318219

E. Carvou, N. Ben Jemaa

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引用次数: 9

Abstract

It is well known that vibrations of contact interfaces are the main cause of contact degradation by the so called fretting corrosion phenomena. In fact the process of generated particles by mechanical wear produce either the increase of contact voltage accompanied with rapid fluctuations. The main objective of this work is to examine the electrical behaviour of contact interface under vibration and characterize theses fluctuations during the fretting. A single point contact is submitted to high number of vibrations (103 to 107) at 100 Hz with an amplitude of 50 mum. The contact is in a resistive circuit supplied by 14 V and 10 A. The contact voltage is acquired with fast sampling oscilloscope and fluctuations are analysed by real time FFT module. We have found that, depending on the degradation stage, the apparition of these fluctuations is attributed to electro-mechanical phenomena. Some slow fluctuations are well correlated to vibration period while the rapid ones are linked to electrical conduction perturbation in granular interface by movement. Furthermore, the self-heating by such high contact voltage at high current levels is examined.

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电源连接器微动诱发接触电压间歇的时间和水平分析

众所周知，接触界面的振动是引起接触退化的主要原因，即所谓的微动腐蚀现象。实际上，机械磨损产生颗粒的过程要么是接触电压的升高，要么是接触电压的快速波动。本工作的主要目的是研究接触界面在振动作用下的电行为，并表征微动过程中的这些波动。单点接触在100 Hz的振幅为50 mum的情况下接受高频率的振动(103至107)。触点位于由14v和10a供电的电阻电路中。采用快速采样示波器采集接触电压，并通过实时FFT模块对接触电压波动进行分析。我们发现，根据降解阶段的不同，这些波动的出现可归因于机电现象。一些慢波动与振动周期密切相关，而快速波动则与运动引起的颗粒界面电导扰动有关。此外，还研究了这种高接触电压在高电流水平下的自热现象。

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Electrical Contacts - 2007 Proceedings of the 53rd IEEE Holm Conference on Electrical Contacts

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