Bending and stress analysis of polymeric composite plates reinforced with functionally graded graphene platelets based on sinusoidal shear-deformation plate theory

Received: 02 Jan 2021, Revised: 10 Jan 2021 , Accepted: 25 Mar 2021, Available online: 29 Mar 2021, Version of Record: 29 Mar 2021

Mohammad Arefi, Ali Tabatabaeian, Masoud Mohammadi
Faculty of Mechanical Engineering, Department of Solid Mechanics, University of Kashan, Kashan 87317-51167, Iran

Abstract


The bending and stress analysis of a functionally graded polymer composite plate reinforced with graphene platelets are studied in this paper. The governing equations are derived by using principle of virtual work for a plate which is rested on Pasternak’s foundation. Sinusoidal shear deformation theory is used to describe displacement field. Four different distribution patterns are employed in our analysis. The analytical solution is presented for a functionally graded plate to investigate the influence of important parameters. The numerical results are presented to show the deflection and stress results of the problem for four employed patterns in terms of geometric parameters such as number of layers, weight fraction and two parameters of Pasternak’s foundation.

Keywords
Reinforced composite plate
Graphene platelet
Sinusoidal shear deformation theory
Pasternak’s foundation
Stress and deformation analysis



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