Distinct Element Simulation of Mechanical Properties of Hypothetical CNT Nanofabrics

Supercomput. Front. Innov. Pub Date : 2019-06-24 DOI:10.14529/JSFI190208

I. Ostanin

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Abstract

A universal framework for modeling composites and fabrics of micro- and nanofibers, such as carbon nanotubes, carbon fibers and amyloid fibrils, is presented. Within this framework, fibers are represented with chains of rigid bodies, linked with elastic bonds. Elasticity of the bonds utilizes recently developed enhanced vector model formalism. The type of interactions between fibers is determined by their nature and physical length scale of the simulation. The dynamics of fibers is computed using the modification of rigid particle dynamics module of the waLBerla multiphysics framework. Our modeling system demonstrates exceptionally high parallel performance combined with the physical accuracy of the modeling. The efficiency of our technique is demonstrated with an illustrative mechanical test on a hypothetical carbon nanotube textile. In this example, the elasticity of the fibers represents the coarse-grained covalent bond within CNT surface, whereas interfiber interactions represent coarse-grained van der Waals forces between cylindrical segments of nanotubes. Numerical simulation demonstrates stability and extremal strength of a hypothetical carbon nanotube fabric.

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假设碳纳米管纳米织物力学性能的离散元模拟

提出了一种微纳米纤维(如碳纳米管、碳纤维和淀粉样原纤维)复合材料和织物建模的通用框架。在这个框架中，纤维用刚体链表示，用弹性键连接。键的弹性利用最近开发的增强向量模型形式。光纤之间相互作用的类型取决于它们的性质和模拟的物理长度尺度。通过修改waLBerla多物理场框架的刚体粒子动力学模块，计算了纤维的动力学特性。我们的建模系统展示了非常高的并行性能，并结合了建模的物理精度。通过对碳纳米管织物的力学测试，证明了该技术的有效性。在这个例子中，纤维的弹性代表了碳纳米管表面的粗粒度共价键，而纤维间的相互作用代表了纳米管圆柱形段之间的粗粒度范德华力。数值模拟证明了碳纳米管织物的稳定性和极限强度。

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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Supercomput. Front. Innov.

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