Multiscale model construction and modulus prediction of needle-punched carbon/carbon composites

Polymers and Polymer Composites Pub Date : 2023-02-17 DOI:10.1177/09673911231158999

Yang Liu, Hai-tao Zhao, S. Dong, Xiaoguang Zhao, Yahui Peng, Jian Chen

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引用次数: 1

Abstract

In this paper, the modulus prediction of NP-C/C is completed by establishing a multiscale finite element model, and the influence weight analysis of the modulus is carried out by using the analytical homogenization method. Firstly, three Micro-RVE, including unidirectional composites, short fiber reinforced composites and porous matrix, are established to characterize the layers of NP-C/C. Then, the finite element model is used for homogenization and passed upward into Meso-RVE, and the modulus prediction is completed. Finally, the analytical homogenization method is used combined with the MATLAB® script to analyze the influence weight of the modulus by adjusting the parameters. The results show that the average errors of stiffness coefficient prediction values obtained based on the analytical homogenization method are only 6.0% relative to the experimental values, which are lower than 25.3% of the finite element model. The modulus prediction method given in this study does not need to establish a micromechanical model with complex structure, and can be directly completed by computer script when the prediction accuracy is met, which is simple and feasible.

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针刺碳/碳复合材料多尺度模型构建及模量预测

本文通过建立多尺度有限元模型完成了NP-C/C的模量预测，并采用解析均质法进行了模量的影响权分析。首先，建立了单向复合材料、短纤维增强复合材料和多孔基体3种微观rve，表征了NP-C/C的层数;然后利用有限元模型进行均匀化，向上传递到Meso-RVE，完成模量预测。最后，利用解析均质法结合MATLAB®脚本，通过调整参数来分析模量的影响权重。结果表明，基于解析均匀化方法的刚度系数预测值相对于实验值的平均误差仅为6.0%，低于有限元模型的25.3%。本文给出的模量预测方法不需要建立结构复杂的微观力学模型，在满足预测精度的情况下可直接通过计算机脚本完成，简单可行。

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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Polymers and Polymer Composites

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