There has been a great upsurge in research and failure analysis on automotive interconnections over the past 10 years. Failures are often attributed to a combination of loss of normal force, fretting corrosion, general corrosion, overheating, plating degradation, and others. Much of the research effort has been to establish a reproducible link between material system and electrical performance reliability. Metal alloy producers and material platers have attempted to contribute to this effort by performing specific coupon studies which characterize the electrical performance of their products. Generally, these coupon studies do not address the critical differences between the performance of a flat coupon sample and a formed connector. Within the automotive industry, there are various performance tests applied to interconnection components which evaluate electrical performance results after simulated or accelerated service conditions. This paper describes the development of a test method which is capable of simulating the key performance characteristics of an automotive interconnection. Recommendations for future improvements are included. The goal of this development was to provide a testing system which evaluates the degradation of contact resistance in samples which closely represent formed components, without the encumbrance of complete component fabrication. The following criteria were selected as minimum test system requirements : Samples must be easily fabricated from the material systems of interest; The environment must provide for thermal cycling (Delta T=125/spl deg/C, min.); Provide for stress relaxation of a formed contact spring to manifest in the performance resu Provide for the motion required for fretting corrosion at the contact surface; The change in contact resistance with time must be measured at intervals close enough to identify critical phenomena; Samples must be easily retrieved and prepared for contact surface analysis after cycle testing is completed. Initial results comparing heavy hot tin coatings on both brass and copper beryllium show an extremely high difference in the rate of increase in contact resistance.
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机译:在过去的10年中,汽车互连的研究和故障分析一直在迅速发展。失效通常归因于法向力损失,微动腐蚀,全面腐蚀,过热,镀层退化等。许多研究工作都是在材料系统和电气性能可靠性之间建立可重现的联系。金属合金生产商和材料电镀商已尝试通过进行表征其产品电性能的特定试样研究来为这一努力做出贡献。通常,这些试样研究不能解决平板试样和成形连接器性能之间的关键差异。在汽车行业内,互连组件已进行了各种性能测试,这些测试在模拟或加速使用条件后评估电气性能结果。本文介绍了一种能够模拟汽车互连的关键性能特征的测试方法的开发。包括未来改进的建议。该开发的目的是提供一种测试系统,该系统评估紧密地代表所形成的部件的样品中的接触电阻的劣化,而不会妨碍完整的部件制造。选择以下标准作为最低测试系统要求:样品必须易于从感兴趣的材料系统中制造出来;该环境必须提供热循环(Delta T = 125 / spl deg / C,最小值);提供所形成的接触弹簧的应力松弛以体现性能结果;提供在接触面上进行微动腐蚀所需的运动;必须以足够接近的时间间隔测量接触电阻随时间的变化,以识别关键现象。循环测试完成后,必须易于取回样品并准备进行接触表面分析。比较黄铜和铍青铜上较厚的热锡涂层的初步结果表明,接触电阻的增加速率存在极高的差异。
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