Size dependent nano-spherical pressure vessels based on strain gradient theory

Q4 Chemical Engineering Applied and Computational Mechanics Pub Date : 2021-06-01 DOI:10.22059/JCAMECH.2021.322571.612
E. Zarezadeh, M. Najafzadeh, A. Barati
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引用次数: 1

Abstract

This study investigates the effect of size scale material parameters on stress distribution and radial displacement of nanosphere based on strain gradient theory. This model is more capable of studying mechanical behavior than classical elasticity theory as the size scale effect of the nanosphere is also considered. Minimum total potential energy is used to derive governing differential equation of nanosphere under internal hydrostatic pressure. Using the efficient numerical generalized differential quadrature (GDQ) method, the governing equation and corresponding boundary conditions are solved. The classical elasticity equation is obtained by setting the value of size scale material parameters to zero. With the comparison of these theories, the importance of the size scale material parameters is achieved. It is found that the radial displacement of nanosphere predicted by strain gradient theory is less than those predicted by classical elasticity theory but comparing the distribution of stress components along radius is more complex. The effect of the size of the nanosphere on the radial stress components is also studied. With an increasing outer radius of the nanosphere, the mechanical behavior predicted by strain gradient theory tends toward those in classical elasticity theory.
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基于应变梯度理论的尺寸相关纳米球形压力容器
基于应变梯度理论,研究了尺寸尺度材料参数对纳米球应力分布和径向位移的影响。该模型比经典弹性理论更能研究力学行为,因为还考虑了纳米球的尺寸尺度效应。利用最小总势能推导了纳米球在内部静水压力作用下的控制微分方程。采用有效的数值广义微分求积(GDQ)方法,求解了控制方程和相应的边界条件。通过将尺寸尺度材料参数的值设置为零,可以获得经典的弹性方程。通过对这些理论的比较,得出了尺寸尺度材料参数的重要性。研究发现,应变梯度理论预测的纳米球径向位移小于经典弹性理论预测的径向位移,但比较应力分量沿半径的分布更为复杂。还研究了纳米球尺寸对径向应力分量的影响。随着纳米球外径的增加,应变梯度理论预测的力学行为趋于经典弹性理论预测的行为。
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来源期刊
Applied and Computational Mechanics
Applied and Computational Mechanics Engineering-Computational Mechanics
CiteScore
0.80
自引率
0.00%
发文量
10
审稿时长
14 weeks
期刊介绍: The ACM journal covers a broad spectrum of topics in all fields of applied and computational mechanics with special emphasis on mathematical modelling and numerical simulations with experimental support, if relevant. Our audience is the international scientific community, academics as well as engineers interested in such disciplines. Original research papers falling into the following areas are considered for possible publication: solid mechanics, mechanics of materials, thermodynamics, biomechanics and mechanobiology, fluid-structure interaction, dynamics of multibody systems, mechatronics, vibrations and waves, reliability and durability of structures, structural damage and fracture mechanics, heterogenous media and multiscale problems, structural mechanics, experimental methods in mechanics. This list is neither exhaustive nor fixed.
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