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以聚合物作为各向异性渗透介质的碳纤维浸渍数值模拟

Numerical Simulations of Carbon-Fibre Impregnation with a Polymer as an Anisotropic Permeability Medium.

作者信息

Gomes Daniel, Amorim Luís, Santos Raquel M, Gonçalves Nelson D

机构信息

Institute of Science and Innovation in Mechanical and Industrial Engineering (INEGI), Rua Dr. Roberto Frias, 400, 4200-465 Porto, Portugal.

LAETA-Associated Laboratory of Energy, Transports and Aerospace, 4200-265 Porto, Portugal.

出版信息

Materials (Basel). 2023 Oct 10;16(20):6627. doi: 10.3390/ma16206627.

DOI:10.3390/ma16206627
PMID:37895609
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10608615/
Abstract

The impregnation process of carbon fibres with polymers is challenging to model due to the system's complexity, particularly concerning the following aspects: the complex rheology of the polymeric matrices and the presence of solid, continuous fibres, both with anisotropic properties, and the interaction between solid and fluid, which can change the displacement of fibres into a cyclic dependence. In this work, an interesting approach was considered by setting the fibres as a porous medium whose properties were calculated with microscale/macroscale cycle modelling. In the microscale modelling stage, two main assumptions can be made: (i) a homogeneous distribution with a representative cell or (ii) a stochastic distribution of fibres. The solution to the abovementioned flow and fibre distribution problem can severely differ with only a slight change in a single parameter for a given set of processing parameters. Therefore, the influence of some of them during the fibre impregnation process was evaluated, allowing a shortcut for the polymer through a gap between fibres and the bottom wall of the extrusion die. The range of investigated values regarding the gap enables one to cover good impregnation conditions up to the occurrence of the shortcut and consequent poor impregnation quality. These studies were performed with numerical simulations with circa 126,000 degrees of freedom, considering the discretisation mesh elements and the unknowns (pressure and two velocity components).

摘要

由于该系统的复杂性,碳纤维与聚合物的浸渍过程很难进行建模,尤其是在以下几个方面:聚合物基体复杂的流变学特性、具有各向异性特性的固态连续纤维的存在,以及固体与流体之间的相互作用,这种相互作用会使纤维的位移变成一种循环依赖关系。在这项工作中,考虑了一种有趣的方法,即将纤维设置为一种多孔介质,其特性通过微观/宏观循环建模来计算。在微观建模阶段,可以做出两个主要假设:(i) 具有代表性单元的均匀分布或 (ii) 纤维的随机分布。对于给定的一组加工参数,仅单个参数的微小变化就可能使上述流动和纤维分布问题的解决方案有很大不同。因此,评估了其中一些参数在纤维浸渍过程中的影响,即聚合物通过纤维与挤出模头底壁之间的间隙形成一条捷径。所研究的间隙值范围能够涵盖直至出现捷径及随之而来的浸渍质量变差之前的良好浸渍条件。这些研究是通过具有约126,000个自由度的数值模拟进行的,其中考虑了离散化网格单元和未知数(压力和两个速度分量)。

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