Abstract
Due to the excellent mechanical properties of doubly curved structure and functionally graded porous (FGP) material, the study of their vibration characteristics has attracted wide attention. The main aim of this research is to establish a formulation for free and forced vibration analysis of a new Sandwich FGP doubly curved structure. Four models of Sandwich materials are considered. The potential energy and kinetic energy functions are obtained on the foundation of the first-order shear deformation theory (FSDT). The idea of domain energy decomposition is applied to the theoretical modeling, where the structure is segmented along the generatrix direction. The continuity conditions for the interfaces between adjacent segments are balanced by the weighted parameters. For each segment, the displacement functions are selected as the Jacobi orthogonal polynomials and trigonometric series. The boundary conditions of the structure are obtained by the boundary spring simulation technique. The solution is obtained by the variational operation of the structural functional. The convergence performance and correctness of the theoretical model are examined by several numerical examples. Finally, some novel results are given, where free and forced vibration characteristics of Sandwich FGP doubly curved structures are examined in detail.
Highlights
Zenkour [16, 17] conducted the bending and free vibration analysis of functionally graded (FG) ceramicmetal Sandwich plates by proposing a two-dimensional solution
The Sandwich structure combined with functionally graded porous (FGP) materials has not been investigated yet. e objective of the paper is to establish a model for free and forced vibration analysis of a new Sandwich FGP doubly curved structure based on the semianalytical method
Is paper aims to construct a vibration analysis model for Sandwich FGP doubly curved shell subjected to arbitrary boundary conditions based on the first-order shear deformation theory (FSDT), where four Sandwich material models are considered. e domain energy decomposition technique is employed, which can make the selection of displacement functions become rather flexible. e weighted parameters are utilized to deal with the continuity conditions between each neighbored segment
Summary
Zenkour [16, 17] conducted the bending and free vibration analysis of functionally graded (FG) ceramicmetal Sandwich plates by proposing a two-dimensional solution. Some novel results are given, where free and forced vibration characteristics of Sandwich FGP doubly curved structures are examined in detail.
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