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Abstrakty
In practical applications, sandwich plates are often connected to other members, supported by damaged clamped/simply supported boundary conditions or supported by elastic restraints. Therefore, the mentioned structures may not always be simulated by the classical boundary conditions, i.e., ideal simply supported, clamped and free edges. Also, these structures may be subjected to various loads. In this study, for the first time, a novel economical analytical solution procedure is presented for axisymmetric static analysis of sandwich annular plates, by using the layerwise and 3D elasticity theories. Based on the proposed approach, functionally graded sandwich annular plates with various elastically restrained edges under arbitrary distributed loads may be analyzed and all of the displacements and stresses components may be exactly achieved. Also, imposed loads at the boundaries may be evaluated. Transverse shear and normal stresses boundary conditions on the top and bottom of the sandwich plate and the interlaminar continuity conditions of the in-plane displacement, transverse shear and normal stresses are exactly satisfied. Accuracy and efficiency of the presented solution procedure are demonstrated by comparing the obtained results for sandwich plates with the classical edge conditions as some special cases of the elastic supports with results of the three-dimensional theory of elasticity.
Czasopismo
Rocznik
Tom
Strony
678--694
Opis fizyczny
Bibliogr. 34 poz., rys., tab., wykr.
Twórcy
autor
- Department of Mechanical Engineering, University of Mazandaran, Babolsar 47416-13534, Iran
Bibliografia
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- [21] S.M.R. Khalili, M. Shariyat, I. Rajabi, A finite element based global-local theory for static analysis of rectangular sandwich and laminated composite plates, Composite Structures 107 (2014) 177–189.
- [22] M.M. Alipour, M. Shariyat, Analytical stress analysis of annular FGM sandwich plates with non-uniform shear and normal tractions, employing a zigzag-elasticity plate theory, Aerospace Science and Technology 32 (2014) 235–259.
- [23] M.M. Alipour, M. Shariyat, Analytical zigzag formulation with 3D elasticity corrections for bending and stress analysis of circular/annular composite sandwich plates with auxetic cores, Composite Structures 132 (2015) 175–197.
- [24] M.K. Pandit, A.H. Sheikh, B.N. Singh, An improved higher order zigzag theory for the static analysis of laminated sandwich plate with soft core, Finite Elements in Analysis and Design 44 (2008) 602–610.
- [25] R. Sahoo, B.N. Singh, A new shear deformation theory for the static analysis of laminated composite and sandwich plates, International Journal of Mechanical Sciences 75 (2013) 324–336.
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- [31] M.M. Alipour, M. Shariyat, An elasticity-equilibrium-based zigzag theory for axisymmetric bending and stress analysis of the functionally graded circular sandwich plates, using a Maclaurin-type series solution, European Journal of Mechanics A: Solids 34 (2012) 78–101.
- [32] M.M. Alipour, M. Shariyat, An analytical global-local Taylor transformation-based vibration solution for annular FGM sandwich plates supported by nonuniform elastic foundations, Archives of Civil and Mechanical Engineering 14 (2014) 6–24.
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- [34] M.M. Alipour, An analytical approach for bending and stress analysis of cross/angle-ply laminated composite plates under arbitrary non-uniform loads and elastic foundations, Archives of Civil and Mechanical Engineering 16 (2) (2016) 193–210.
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ce09bba6-24ad-4023-924b-6c7eaaf3afdb