Prediction of shape distortions in thermosetting composite parts using neural network interfaced visco-elastic constitutive model

IF 2.3 3区 材料科学 Q3 MATERIALS SCIENCE, COMPOSITES
Aravind Balaji, Claudio Sbarufatti, David Dumas, Antoine Parmentier, Olivier Pierard, Francesco Cadini
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Abstract

The work aims to enhance the capabilities of a Finite Element tool, specifically related to a rheological thermo-chemo-viscoelastic constitutive model. This enhancement is intended to improve the tool’s ability to predict the distortions in composite parts caused by the polymerization of the thermoset composite matrix. These distortions occur due to internal residual stress generated by the inherent anisotropic properties of the thermoset composite material, including coefficients of thermal expansion and chemical shrinkage. The research work’s improvement is tied to the precise modelling of curing behaviour, which literature acknowledges as having a significant impact on manufacturing defects. In order to accommodate the influence of curing behaviour on various process variables—specifically, different thermal loading rates—a neural network model is implemented as an alternative to a standard diffusion cure-kinetics model. The neural network model is trained using Differential Scanning Calorimetry data and is integrated with the classical visco-elastic constitutive model to more accurately predict the progression of distinct thermoset resin states. This transition between cure states is assessed using two cure state variables: the degree of cure and the glass transition temperature. The enhanced predictions of state transitions lead to accurate assessments of internal residual stresses, especially when dealing with thick components subjected to thermal fluctuations. The anisotropic properties of thermoset composites, crucial for numerical analysis, are captured at various stages of cure. Ultimately, this methodology is employed to compare process-induced defects in the case study of the Z-shaped carbon/epoxy woven part, and the defects closely align with experimental measurements.
利用神经网络接口粘弹性结构模型预测热固性复合材料部件的形状变形
这项工作旨在增强有限元工具的功能,特别是与流变热-热-粘弹性构成模型有关的功能。这一改进旨在提高该工具预测热固性复合材料基体聚合引起的复合材料部件变形的能力。这些变形是由于热固性复合材料固有的各向异性(包括热膨胀系数和化学收缩系数)产生的内部残余应力造成的。这项研究工作的改进与固化行为的精确建模息息相关,文献承认固化行为对制造缺陷有重大影响。为了适应固化行为对各种工艺变量的影响,特别是不同的热负荷率,我们采用了神经网络模型来替代标准的扩散固化动力学模型。神经网络模型使用差示扫描量热数据进行训练,并与经典的粘弹性构成模型相结合,以更准确地预测不同热固性树脂状态的进展。固化状态之间的过渡是通过两个固化状态变量来评估的:固化程度和玻璃化转变温度。对状态转变的预测增强了对内部残余应力的准确评估,尤其是在处理受热波动影响的厚部件时。热固性复合材料的各向异性对数值分析至关重要,在固化的各个阶段都能捕捉到。最终,在 Z 形碳/环氧编织部件的案例研究中,采用这种方法比较了工艺引起的缺陷,缺陷与实验测量结果非常吻合。
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来源期刊
Journal of Composite Materials
Journal of Composite Materials 工程技术-材料科学:复合
CiteScore
5.40
自引率
6.90%
发文量
274
审稿时长
6.8 months
期刊介绍: Consistently ranked in the top 10 of the Thomson Scientific JCR, the Journal of Composite Materials publishes peer reviewed, original research papers from internationally renowned composite materials specialists from industry, universities and research organizations, featuring new advances in materials, processing, design, analysis, testing, performance and applications. This journal is a member of the Committee on Publication Ethics (COPE).
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