A hierarchic isogeometric hyperelastic solid-shell

IF 3.7 2区 工程技术 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS
Leonardo Leonetti, Hugo M. Verhelst
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引用次数: 0

Abstract

The present study aims to develop an original solid-like shell element for large deformation analysis of hyperelastic shell structures in the context of isogeometric analysis (IGA). The presented model includes a new variable to describe the thickness change of the shell and allows for the application of unmodified three-dimensional constitutive laws defined in curvilinear coordinate systems and the analysis of variable thickness shells. In this way, the thickness locking affecting standard solid-shell-like models is cured by enhancing the thickness strain by exploiting a hierarchical approach, allowing linear transversal strains. Furthermore, a patch-wise reduced integration scheme is adopted for computational efficiency reasons and to annihilate shear and membrane locking. In addition, the Mixed-Integration Point (MIP) format is extended to hyperelastic materials to improve the convergence behaviour, hence the efficiency, in Newton iterations. Using benchmark problems, it is shown that the proposed model is reliable and resolves locking issues that were present in the previously published isogeometric solid-shell formulations.

Abstract Image

分层等几何超弹性固壳
本研究旨在开发一种独创的类实体壳元素,用于等几何分析(IGA)中超弹性壳结构的大变形分析。所提出的模型包括一个新变量,用于描述壳体厚度的变化,并允许应用在曲线坐标系中定义的未修改的三维构成法则,以及对厚度可变的壳体进行分析。这样,通过利用分层方法增强厚度应变,允许线性横向应变,从而解决了影响标准类实壳模型的厚度锁定问题。此外,为了提高计算效率,并消除剪切锁定和膜锁定,还采用了片状减小积分方案。此外,还将混合积分(MIP)格式扩展到超弹性材料,以改善牛顿迭代的收敛行为,从而提高效率。使用基准问题表明,所提出的模型是可靠的,并解决了以前发表的等几何固壳公式中存在的锁定问题。
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
Computational Mechanics
Computational Mechanics 物理-力学
CiteScore
7.80
自引率
12.20%
发文量
122
审稿时长
3.4 months
期刊介绍: The journal reports original research of scholarly value in computational engineering and sciences. It focuses on areas that involve and enrich the application of mechanics, mathematics and numerical methods. It covers new methods and computationally-challenging technologies. Areas covered include method development in solid, fluid mechanics and materials simulations with application to biomechanics and mechanics in medicine, multiphysics, fracture mechanics, multiscale mechanics, particle and meshfree methods. Additionally, manuscripts including simulation and method development of synthesis of material systems are encouraged. Manuscripts reporting results obtained with established methods, unless they involve challenging computations, and manuscripts that report computations using commercial software packages are not encouraged.
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