Three-dimensional transient analysis of functionally graded cylindrical shells subjected to asymmetric dynamic pressure
سال
: 2013
چکیده: This paper presents an efficient and accurate numerical method based on the three-dimensional (3-D)
elasticity theory for the transient analysis of functionally graded (FG) hollow cylindrical shells subjected to
asymmetric dynamic pressure. The Fourier expansion is employed to describe the displacement components and dynamic pressure in the tangential direction. In addition, the layerwise theory is used to accurately account for the displacement components in the radial direction. The equations of motion and the related boundary conditions are derived using Hamilton ’ s principle. Then, differential
quadrature method (DQM) is implemented to discretize the resulting equations in the both spatial and time domains. The convergence, accuracy and performance of the present method are established through the convergence study and comparison with available results in the literature. Also, the effects of different parameters such as thickness-to-inner radius ratio and boundary conditions on the dynamic behavior of hollow FG cylinders are investigated. The present method can accurately predict transient
displacement and stress with less computational efforts.
elasticity theory for the transient analysis of functionally graded (FG) hollow cylindrical shells subjected to
asymmetric dynamic pressure. The Fourier expansion is employed to describe the displacement components and dynamic pressure in the tangential direction. In addition, the layerwise theory is used to accurately account for the displacement components in the radial direction. The equations of motion and the related boundary conditions are derived using Hamilton ’ s principle. Then, differential
quadrature method (DQM) is implemented to discretize the resulting equations in the both spatial and time domains. The convergence, accuracy and performance of the present method are established through the convergence study and comparison with available results in the literature. Also, the effects of different parameters such as thickness-to-inner radius ratio and boundary conditions on the dynamic behavior of hollow FG cylinders are investigated. The present method can accurately predict transient
displacement and stress with less computational efforts.
کلیدواژه(گان): asymmetric dynamic pressure,cylindrical shells,differential quadrature method,functionally graded materials,layerwise theory
کالکشن
:
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آمار بازدید
Three-dimensional transient analysis of functionally graded cylindrical shells subjected to asymmetric dynamic pressure
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contributor author | مسعود طهانی | en |
contributor author | Ali Reza Setoodeh | en |
contributor author | احسان سلاحی | en |
contributor author | Masoud Tahani | fa |
contributor author | Ehsan Selahi | fa |
date accessioned | 2020-06-06T13:12:49Z | |
date available | 2020-06-06T13:12:49Z | |
date issued | 2013 | |
identifier uri | https://libsearch.um.ac.ir:443/fum/handle/fum/3346123 | |
description abstract | This paper presents an efficient and accurate numerical method based on the three-dimensional (3-D) elasticity theory for the transient analysis of functionally graded (FG) hollow cylindrical shells subjected to asymmetric dynamic pressure. The Fourier expansion is employed to describe the displacement components and dynamic pressure in the tangential direction. In addition, the layerwise theory is used to accurately account for the displacement components in the radial direction. The equations of motion and the related boundary conditions are derived using Hamilton ’ s principle. Then, differential quadrature method (DQM) is implemented to discretize the resulting equations in the both spatial and time domains. The convergence, accuracy and performance of the present method are established through the convergence study and comparison with available results in the literature. Also, the effects of different parameters such as thickness-to-inner radius ratio and boundary conditions on the dynamic behavior of hollow FG cylinders are investigated. The present method can accurately predict transient displacement and stress with less computational efforts. | en |
language | English | |
title | Three-dimensional transient analysis of functionally graded cylindrical shells subjected to asymmetric dynamic pressure | en |
type | Journal Paper | |
contenttype | External Fulltext | |
subject keywords | asymmetric dynamic pressure | en |
subject keywords | cylindrical shells | en |
subject keywords | differential quadrature method | en |
subject keywords | functionally graded materials | en |
subject keywords | layerwise theory | en |
journal title | Science and Engineering of Composite Materials | fa |
pages | 75-85 | |
journal volume | 20 | |
journal issue | 1 | |
identifier link | https://profdoc.um.ac.ir/paper-abstract-1034534.html | |
identifier articleid | 1034534 |