An embedding-aware continuum thin shell formulation

arXiv - PHYS - Classical Physics Pub Date : 2024-07-05 DOI:arxiv-2407.04894

Abhishek Ghosh, Andrew McBride, Zhaowei Liu, Luca Heltai, Paul Steinmann, Prashant Saxena

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Abstract

Cutting-edge smart materials are transforming the domains of soft robotics, actuators, and sensors by harnessing diverse non-mechanical stimuli, such as electric and magnetic fields. Accurately modelling their physical behaviour necessitates an understanding of the complex interactions between the structural deformation and the fields in the surrounding medium. For thin shell structures, this challenge is addressed by developing a shell model that effectively incorporates the three-dimensional field it is embedded in by appropriately accounting for the relevant boundary conditions. This study presents a model for the nonlinear deformation of thin hyperelastic shells, incorporating Kirchhoff-Love assumptions and a rigorous variational approach. The shell theory is derived from 3D nonlinear elasticity by dimension reduction while preserving the boundary conditions at the top and bottom surfaces of the shell. Consequently, unlike classical shell theories, this approach can distinguish between pressure loads applied at the top and bottom surfaces, and delivers a platform to include multi-physics coupling. Numerical examples are presented to illustrate the theory and provide a physical interpretation of the novel mechanical variables of the model.

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嵌入感知连续薄壳公式

尖端智能材料通过利用各种非机械刺激，如电场和磁场，正在改变软机器人、致动器和传感器等领域。要准确模拟其物理行为，就必须了解结构变形与周围介质中的场之间复杂的相互作用。对于薄壳结构来说，要解决这一难题，就要建立一个壳体模型，通过适当考虑相关边界条件，有效地将其所嵌入的三维场纳入其中。本研究提出了一种超弹性薄壳的非线性变形模型，该模型结合了基尔霍夫-洛夫假设和严格的变分法。壳理论是通过降维从三维非线性弹性中推导出来的，同时保留了壳顶部和底部表面的边界条件。因此，与经典的壳理论不同，这种方法可以区分施加在顶部和底部表面的压力载荷，并提供了一个包含多物理耦合的平台。本研究还提供了数值示例来说明该理论，并对模型的新颖力学变量进行了物理解释。

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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arXiv - PHYS - Classical Physics

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