稳健的有限应变等几何实体梁元素

Abdullah Shafqat, Oliver Weeger, Bai-Xiang Xu
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摘要

在这项工作中,开发了一种有效的、鲁棒的等几何三维实体梁有限元,用于仅以位移作为自由度的大变形和有限迭代。考虑了有限应变理论和超弹性本构模型,采用b样条和nurbs进行有限元离散。与基于拉格朗日多项式的有限元类似,基于nurbs的公式也受到锁定的非物理现象的影响,这限制了场变量,对解的精度产生了负面影响,并恶化了收敛性。为了在固体梁公式中避免这个问题,采用假设自然应变(ANS)方法来缓解膜和横向剪切锁定,并采用增强假设应变(EAS)方法来缓解泊松厚度锁定。此外,采用混合积分点(MIP)方法,提高了公式的有效性和鲁棒性。在多个单块和多块基准问题上对所提出的新型等几何实体梁单元进行了测试,并针对经典实体有限元和等参数实体梁单元进行了验证。结果表明,所提出的配方可以缓解锁紧效应,显著提高等几何实体梁单元的性能。利用所开发的单元,可以有效、准确地预测晶格基结构材料的力学性能。所提出的实体梁单元既继承了实体单元边界条件灵活的优点,又继承了梁单元计算效率高的优点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A robust finite strain isogeometric solid-beam element
In this work, an efficient and robust isogeometric three-dimensional solid-beam finite element is developed for large deformations and finite rotations with merely displacements as degrees of freedom. The finite strain theory and hyperelastic constitutive models are considered and B-Spline and NURBS are employed for the finite element discretization. Similar to finite elements based on Lagrange polynomials, also NURBS-based formulations are affected by the non-physical phenomena of locking, which constrains the field variables and negatively impacts the solution accuracy and deteriorates convergence behavior. To avoid this problem within the context of a Solid-Beam formulation, the Assumed Natural Strain (ANS) method is applied to alleviate membrane and transversal shear locking and the Enhanced Assumed Strain (EAS) method against Poisson thickness locking. Furthermore, the Mixed Integration Point (MIP) method is employed to make the formulation more efficient and robust. The proposed novel isogeometric solid-beam element is tested on several single-patch and multi-patch benchmark problems, and it is validated against classical solid finite elements and isoparametric solid-beam elements. The results show that the proposed formulation can alleviate the locking effects and significantly improve the performance of the isogeometric solid-beam element. With the developed element, efficient and accurate predictions of mechanical properties of lattice-based structured materials can be achieved. The proposed solid-beam element inherits both the merits of solid elements e.g. flexible boundary conditions and of the beam elements i.e. higher computational efficiency.
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