摘要
Fretting wear is a common cause of failure of an electrical contact(EC). In this study, we analyzed in detail the failure of EC induced especially by sliding using the representative electrical terminals. Furthermore, combining the friction energy dissipation theory, we proposed a prediction model to evaluate the electrical connector endurance(ECE) based on the contact stress and geometrical changes during the wear process obtained from a numerical model. The study helps establish that the friction energy dissipation theory is a powerful tool to analyze a contact failure due to wear. The proposed model proves to be effective in predicting the ECE for all considered cases such as micro-slip amplitude, contact force, overturning angle, superficial layer thickness, and friction/wear coefficients.
Fretting wear is a common cause of failure of an electrical contact(EC). In this study, we analyzed in detail the failure of EC induced especially by sliding using the representative electrical terminals. Furthermore, combining the friction energy dissipation theory, we proposed a prediction model to evaluate the electrical connector endurance(ECE) based on the contact stress and geometrical changes during the wear process obtained from a numerical model. The study helps establish that the friction energy dissipation theory is a powerful tool to analyze a contact failure due to wear. The proposed model proves to be effective in predicting the ECE for all considered cases such as micro-slip amplitude, contact force, overturning angle, superficial layer thickness, and friction/wear coefficients.
出处
《Friction》
SCIE
CSCD
2019年第6期537-550,共14页
摩擦(英文版)
基金
the financial support of this work by the National Natural Science Foundation of China (NSFC) under Grant Numbers 51775406 and 51405371
Open Research Fund of State Key Laboratory of Structural Analysis for Industrial Equipment (Grant No. GZ1612)
111 Project B14042
the Fundamental Research Funds for the Central Universities (Grant No. JB180412)
Natural Science Foundation of Shanxi Province of China (Grant No. 2017JM5035)
Natural Science Foundation of Guangxi Province of China (Grant No. 2016GXNSFBA380230)
