Steady-state responses of functionally graded piezoelectric structures by the coupled thermal-electrical-mechanical inhomogeneous cell-based smoothed finite element method (CICS-FEM). (English) Zbl 07446888
Summary: To accurately simulate the steady-state responses of a functionally graded piezoelectric structure (FGPS) and cure the “overly-stiff” of finite element method (FEM), the coupled thermal-electrical-mechanical inhomogeneous cell-based smoothed finite element method (CICS-FEM) is proposed. The gradient smoothing technique is introduced into FEM and a “close-to-exact” stiffness is obtained. Based on the basic theory of FGPS, the thermal field is introduced into the electrical-mechanical coupling field and the multi-physics coupling equations are given in conjunction with the cell-based smoothed finite element method. CICS-FEM is verified with several examples, and there is a satisfactory agreement between the current solution and the reference solution. Therefore, the developed method to solve the steady-state response of FGPS can provide a reference for the design and manufacture of smart devices.
Keywords:
steady-state response; functionally graded piezoelectric structures; coupled thermal-electrical-mechanical inhomogeneous cell-based smoothed finite element method (CICS-FEM); multi-physics couplingReferences:
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