Effective mechanical properties of auxetic materials: Numerical predictions using variational asymptotic method based homogenization

IF 2.6 4区工程技术 Q2 MECHANICS

Journal of Applied Mechanics-Transactions of the Asme Pub Date : 2023-06-28 DOI:10.1115/1.4062845

Chetna Srivastava, V. M., P. Pitchai, P. Guruprasad, N. Petrinic, F. Scarpa, D. Harursampath, Sathiskumar Anusuya Ponnusami

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引用次数: 1

Abstract

In this work, the variational asymptotic method (VAM) based homogenization framework is used for the first time to determine the equivalent elastic stiffness tensor of auxetic materials. The proposed method allows the structural elements of the auxetic unit cell to naturally incorporate rotational degrees of freedom, without any ad-hoc assumptions. The overall macroscale homogenized response of the unit-cells is considered to be fully anisotropic; specific possible responses, representative of orthotropy or transverse isotropy naturally emerge from the VAM-based homogenization, due to the arrangements of the structural elements making up the unit-cell. For all the auxetic unit cell geometries considered in this study, the predictions obtained from the in-house python-based implementation of the VAM-based homogenization framework are validated using commercial finite element software (Abaqus) and open literature. The results demonstrate the versatility and the computational efficiency of the VAM-based homogenization framework to describe auxetic metamaterials.

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增减材料的有效力学性能:基于均质化的变分渐近方法的数值预测

本文首次利用变分渐近方法(VAM)的均匀化框架确定了塑性材料的等效弹性刚度张量。所提出的方法允许辅助单元胞的结构元素自然地结合旋转自由度，而不需要任何特别的假设。单元胞整体宏观均匀响应被认为是完全各向异性的;由于构成单元胞的结构元素的排列，从基于vam的均质化中自然产生了具有代表性的正交异性或横向各向同性的特定可能响应。对于本研究中考虑的所有缺陷单元格几何形状，利用商业有限元软件(Abaqus)和公开文献验证了基于vam的均质化框架的内部python实现所获得的预测。结果表明，基于vam的均匀化框架在描述生长性超材料方面具有通用性和计算效率。

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

Journal of Applied Mechanics-Transactions of the Asme 物理-力学

CiteScore

4.80

自引率

3.80%

发文量

审稿时长

5.8 months

期刊介绍： All areas of theoretical and applied mechanics including, but not limited to: Aerodynamics; Aeroelasticity; Biomechanics; Boundary layers; Composite materials; Computational mechanics; Constitutive modeling of materials; Dynamics; Elasticity; Experimental mechanics; Flow and fracture; Heat transport in fluid flows; Hydraulics; Impact; Internal flow; Mechanical properties of materials; Mechanics of shocks; Micromechanics; Nanomechanics; Plasticity; Stress analysis; Structures; Thermodynamics of materials and in flowing fluids; Thermo-mechanics; Turbulence; Vibration; Wave propagation