Solution of the dynamic frictional contact problem between a functionally graded coating and a moving cylindrical punch

• Published in: International journal of solids and structures Vol. 161; pp. 267 - 281
• Main Authors: Balci, Mehmet N., Dag, Serkan
• Format: Journal Article
• Language: English
• Published: New York Elsevier Ltd 01.04.2019; Elsevier BV
• Subjects: Boundary conditions; Coefficient of friction; Collocation methods; Contact stress; Contact stresses; Dynamic contact mechanics; Elastodynamics; Elastostatics; Fourier transforms; Frictional moving cylindrical punch; Functionally graded coating; Functionally gradient materials; Inhomogeneity; Integral equations; Partial differential equations; Singular integral equation; Singular integral equations; Functionally graded coating; Singular integral equation; Dynamic contact mechanics; Contact stress; Frictional moving cylindrical punch
• ISSN: 0020-7683; 1879-2146
• DOI: 10.1016/j.ijsolstr.2018.11.020

•Analytical method is developed to solve dynamic contact problem of graded coatings.•The rigid cylindrical punch moves at a constant speed on the graded coating.•The singular integral equation is solved to reveal the elastodynamic effects.•Results of the present analytical method are verified by comparison studies.•Dynamic effect on contact stresses due to punch speed is found to be significant. This paper presents an analytical method developed to investigate the dynamic frictional contact mechanics between a functionally graded coating and a rigid moving cylindrical punch. Governing partial differential equations of elastodynamics are solved analytically by applying Galilean and Fourier transformations. Interface continuity and boundary conditions are written and contact problem is then reduced to a singular integral equation of the second kind. The singular integral equation is solved numerically by means of an expansion-collocation method. Developed solution procedures are verified through the comparisons made to the results available in the literature. Presented parametric analyses illustrate the effects of punch speed, coefficient of friction, material inhomogeneity and geometric parameters upon the contact stresses. It is shown that, especially at higher punch speeds, the difference between contact stresses obtained through elastodynamic and elastostatic solutions is rather significant. A formulation based on the elastodynamic theory, as presented in the current study, is required to compute more realistic contact stresses.