Thermal insulation effect on EHL of coated cam/tappet contact during start up

润滑 材料科学 雷诺方程 机械 涂层 摩擦损失 复合材料 机械工程 法律工程学 工程类 湍流 雷诺数 物理
作者
Xianghui Meng,Changya Yu,Youbai Xie,Benfu Mei
出处
期刊:Industrial Lubrication and Tribology [Emerald Publishing Limited]
卷期号:70 (6): 917-926 被引量:7
标识
DOI:10.1108/ilt-03-2016-0065
摘要

Purpose This paper aims to investigate the lubrication performance of cam/tappet contact during start up. Especially, the thermal insulation effects of coating on the lubrication performance during cold start up process and warm start up process are studied. Design/methodology/approach A numerical model for the analysis of thermal elastohydrodynamic lubrication of coated cam/tappet contact is presented. In this model, the Reynolds equation and the energy equations are discretized by the finite difference method and solved jointly. Findings During start up, the contact force at cam nose-to-tappet contact decreases with increasing time, while the absolute entrainment velocity has the upward trend. The minimum film thickness, maximum average temperature and friction power loss increase with increasing time, while the coefficient of friction decreases during start up. Because of the thermal insulation effect, the coating can significantly increase the degree of temperature rise. Compared with the uncoated case, the coated cam/tappet results in a lower friction power loss. Generally, the friction power loss in the cold start up process is much higher than that in the warm start up process. Originality/value By this study, the lubrication performance and the kinematics and the dynamics of the cam/tappet during start up process are investigated. Meanwhile, the thermal insulation effect of coating is also illustrated. The difference of lubrication performance between cold start up process and warm start up process is analyzed. The results and thermal elastohydrodynamic lubrication method presented in this study can be a guidance in the design of the coated cam/tappet.

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