A general element for shell analysis based on the scaled boundary finite element method

IF 2.7 3区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY
Gao Lin, Wenbin Ye, Zhiyuan Li
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Abstract

A novel technique, the scaling surface-based Scaled Boundary Finite Element Method (SBFEM), is introduced as a method for formulating a general element for shell analysis. This displacement-based element includes three translational degrees of freedom (DOFs) per node. Notably, only two-dimensional discretization for one of the two parallel shell surfaces, referred to as the scaling surface, is necessary. The interpolation scheme for the scaling surface is postulated to be applicable to all surfaces parallel to it in the thickness. The derivation strictly adheres to the 3D theory of elasticity, without making additional kinematic assumptions. As a result, the displacement field along the thickness is analytically solved, and the element formulation is immune to transverse locking, membrane locking, and other issues, eliminating the need for additional remedies. Extensive investigations into the robustness and accuracy of the elements have been conducted using well-known benchmark problems, along with additional challenging problems. Numerical examples confirm that the element formulation is free from transverse shear locking and membrane locking. Moreover, the proposed formulation is easily extendable to cases involving shell elements with varying thickness and holds the potential for extension to the nonlinear response analysis of shell structures.

基于比例边界有限元法的壳体分析通用元素
本文介绍了一种新技术,即基于缩放面的缩放边界有限元法(SBFEM),它是一种用于壳体分析的通用元素。这种基于位移的元素包括每个节点的三个平移自由度(DOF)。值得注意的是,只需对两个平行壳体表面中的一个(称为缩放面)进行二维离散化。缩放面的插值方案假定适用于厚度上与之平行的所有表面。推导过程严格遵循三维弹性理论,不做额外的运动学假设。因此,沿厚度方向的位移场可通过分析求解,而且元素公式不受横向锁定、膜锁定和其他问题的影响,无需额外的补救措施。我们利用著名的基准问题和其他具有挑战性的问题,对元素的稳健性和准确性进行了广泛研究。数值示例证实,该元素公式不存在横向剪切锁定和膜锁定问题。此外,所提出的公式很容易扩展到涉及厚度不同的壳元素的情况,并有可能扩展到壳结构的非线性响应分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
5.70
自引率
6.90%
发文量
276
审稿时长
5.3 months
期刊介绍: The International Journal for Numerical Methods in Engineering publishes original papers describing significant, novel developments in numerical methods that are applicable to engineering problems. The Journal is known for welcoming contributions in a wide range of areas in computational engineering, including computational issues in model reduction, uncertainty quantification, verification and validation, inverse analysis and stochastic methods, optimisation, element technology, solution techniques and parallel computing, damage and fracture, mechanics at micro and nano-scales, low-speed fluid dynamics, fluid-structure interaction, electromagnetics, coupled diffusion phenomena, and error estimation and mesh generation. It is emphasized that this is by no means an exhaustive list, and particularly papers on multi-scale, multi-physics or multi-disciplinary problems, and on new, emerging topics are welcome.
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