初始连接器插入对电接触电阻的影响

R. Jackson, W. Ashurst, G. Flowers, S. Angadi, S. Choe, M. Bozack
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引用次数: 13

摘要

这项工作试图量化重复初始连接器插入和粗糙度对电接触电阻的影响。实验测量表明,随着重复插入,电接触电阻显著增加。他们还表明,随着重复插入,连接器弹簧会发生塑性变形,从而导致关闭接触面的力减小。采用多尺度粗糙表面接触模型估计了连接器的实际接触电阻(ECR)随外力的变化曲线。正如预期的那样,多尺度ECR模型预测ECR会随着施加力的增加而减小。由于接触力随着连接器的每次插入而减少,由于塑性变形,该模型将预测ECR也会随着每次插入而增加。当考虑氧化锡可测层的附加电阻时,多尺度ECR模型与实验结果吻合较好。
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The Effect of Initial Connector Insertions on Electrical Contact Resistance
This work attempts to quantify the effect of repeated initial connector insertions and roughness on electrical contact resistance. Experimental measurements show that the electrical contact resistance increases measurably with repeated insertions. They also show that with repeated insertions the connector spring is plastically deformed, thus causing the force closing the contact across the surfaces to decrease. A multi-scale rough surface contact model was used to estimate the actual electrical contact resistance (ECR) versus applied force curve of the connector. As expected, the multiscale ECR model predicts that the ECR will decrease with applied force. Since the contact force decreases with each insertion of the connector due to plastic deformation, the model will predict that the ECR will also increase with each insertion. When the added resistance from a measurable layer of tin oxide is included, the multiscale ECR model shows fairly good agreement with the experimental measurements.
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