A numerical procedure is developed for the analysis of transient thermoelastohydrodynamic (TEHD) behavior of connecting-rod bearings under dynamic loading. The Reynolds and energy equations in the film and heat transfer equation in the solids are all solved using the Newton-Raphson method and the finite element formulation. The finite element meshes of the three domains are interconnected, and so the heat flux continuity conditions become implicit. As a consequence, the study of complicated structures, such as actual connecting-rod bearings, can be handled and boundary conditions can easily be changed. [S0742-4787(00)02301-8]

Issue Section:
Technical Papers
Keywords:
elastic deformation, lubrication, machine bearings, thermal analysis, thermoelasticity
Topics:
Bearings, Deformation, Temperature, Film thickness, Dynamic testing (Materials), Transients (Dynamics), Lubrication
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