期刊
MATHEMATICS
卷 10, 期 7, 页码 -出版社
MDPI
DOI: 10.3390/math10071081
关键词
mathematical modeling; eigenvalue; PDEs; nanocomposites; cylindrical shell; critical temperature
类别
This study aims to mathematically model the thermoelastic stability of cylindrical shells reinforced with carbon nanotubes (CNTs) and evaluate the effects of CNT patterns, volume fraction, and geometric parameters on the critical temperature by comparing with classical theory.
Revolutionary advances in technology have led to the use of functionally graded nanocomposite structural elements that operate at high temperatures and whose properties depend on position, such as cylindrical shells designed as load-bearing elements. These advances in technology require new mathematical modeling and updated numerical calculations to be performed using improved theories at design time to reliably apply such elements. The main goal of this study is to model, mathematically and within an analytical solution, the thermoelastic stability problem of composite cylinders reinforced by carbon nanotubes (CNTs) under a uniform thermal loading within the shear deformation theory (ST). The influence of transverse shear deformations is considered when forming the fundamental relations of CNT-patterned cylindrical shells and the basic partial differential equations (PDEs) are derived within the modified Donnell-type shell theory. The PDEs are solved by the Galerkin method, and the formula is found for the eigenvalue (critical temperature) of the functionally graded nanocomposite cylindrical shells. The influences of CNT patterns, volume fraction, and geometric parameters on the critical temperature within the ST are estimated by comparing the results within classical theory (CT).
作者
我是这篇论文的作者
点击您的名字以认领此论文并将其添加到您的个人资料中。
推荐
暂无数据