The tangential stiffness matrix of Mooney-Rivlin model strain energy function-based rubber material in finite element method

机译：基于Mooney-Rivlin模型应变能函数的橡胶材料的切向刚度矩阵的有限元方法

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The tangential constitutive matrix is derived in the paper for the nonlinear finite element computation of rubber material as the strain energy function is expressed by Mooney-Rivlin model. The stress and strain of constitutive relation are separately expressed by Piola-Kirchhoff stress and Green strain with Lagrange description. As the incompressibility considered, the strain energy function is decoupled into volume -preserving and dilatational parts. The tangential stiffness matrix is then attained by use of the tangential constitutive matrix. The stiffness matrix is developed to nonlinear finite element computation of hyperelastic material.

机译：由于门尼-里夫林模型表达了应变能函数，因此得出了切向本构矩阵，用于橡胶材料的非线性有限元计算。本构关系的应力和应变分别用Piola-Kirchhoff应力和具有Lagrange描述的格林应变表示。考虑到不可压缩性，应变能函数被分解为体积保留部分和膨胀部分。然后通过使用切向本构矩阵获得切向刚度矩阵。刚度矩阵被开发用于超弹性材料的非线性有限元计算。

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《2011 Second International Conference on Mechanic Automation and Control Engineering》|2011年|p.4633-4635|共3页
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Zhi-Yu Wang; An-Wen Wang;
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中图分类计算技术、计算机技术;
关键词
Hyperelastic; Mooney-Rivlin model; Rubber; Tangential stiffness matrix;

机译：超弹性; Mooney-Rivlin模型;橡胶;切向刚度矩阵;

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1. On the performance of enhanced strain finite elements in large strain deformations of elastic shells: Comparison of two classes of constitutive models for rubber materials [J] . Carlo Sansour, Stefanie Feih, Werner Wagner Engineering Computations . 2003,第7a8期

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3. CORRECTION OF A STIFFNESS MATRIX OF STEEL MATERIALS IN A FINITE ELEMENT MODEL USING ARTIFICIAL NEURAL NETWORKS [J] . Yang Zhong, Sun Gang, Si Haifei Journal of investigative medicine . 2014,第8Suppla1期

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4. The Tangential Stiffness Matrix of Mooney-Rivlin Model Strain Energy Function-based Rubber Material in Finite Element Method [C] . Zhi-Yu Wang, An-Wen Wang International Conference on Mechanic Automation and Control Engineering . 2011

机译：有限元法中的Mooney-rivlin模型应变能功能型橡胶材料的切向刚度矩阵
5. Modeling crash dynamic responses of high energy absorbing materials by multi-body, non-linear finite element, and optimization methods. [D] . Wu, Fubang. 1995

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6. A Coupled Experiment-finite Element Modeling Methodology for Assessing High Strain Rate Mechanical Response of Soft Biomaterials [O] . Rajkumar Prabhu, Wilburn R. Whittington, Sourav S. Patnaik, 2015

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7. Optimization method for the determination of Mooney-Rivlin material coefficients of the human breasts in-vivo using static and dynamic finite element models [O] . Yue Sun, Lihua Chen, Kit-lun Yick, 2019

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The tangential stiffness matrix of Mooney-Rivlin model strain energy function-based rubber material in finite element method

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