Coupled 3D non-orthogonal constitutive model for woven composites in preforming and compaction processes

IF 1.9 Q3 ENGINEERING, MANUFACTURING Manufacturing Letters Pub Date : 2024-10-01 DOI:10.1016/j.mfglet.2024.09.049

Deyong Sun , Wanrui Zhang , Jianchao Zou , Yifeng Xiong , Chongrui Tang , Weizhao Zhang

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Abstract

Woven composites are considered promising for lightweight applications with great environmental and economic benefits. One of the most promising techniques for mass-production of woven composite parts with complex geometry is closed-mold thermoforming including preforming, compaction/consolidation and curing steps. The ignored effects on non-uniform thickness deformation and compaction modulus caused by preforming are considered in the coupled 3D non-orthogonal constitutive model to capture the coupled material behaviors during preforming and compaction. The in-plane tension, compression and shear modulus in the model are calibrated using tension, bending and bias-extension experiments, respectively. Meanwhile, the out-plane compaction experiments are designed, with high-accuracy measurement method for the initial thickness and deformation process, to obtain the material properties of sheared woven composites. These experiments can be regarded as one benchmark for compaction tests of woven composites. The new material model has been implemented in Abaqus software and validated by the bias-extension experiments.

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预成型和压实过程中编织复合材料的三维非正交耦合结构模型

编织复合材料在轻量化应用方面前景广阔，具有巨大的环境和经济效益。大规模生产具有复杂几何形状的编织复合材料部件的最有前途的技术之一是闭模热成型，包括预成型、压实/固化和固化步骤。在耦合三维非正交结构模型中考虑了预成型对非均匀厚度变形和压实模量的影响，以捕捉预成型和压实过程中的耦合材料行为。模型中的平面内拉伸模量、压缩模量和剪切模量分别通过拉伸、弯曲和偏拉伸实验进行校准。同时，设计了平面外压实实验，采用高精度测量方法测量初始厚度和变形过程，以获得剪切编织复合材料的材料特性。这些实验可视为编织复合材料压实试验的基准之一。新材料模型已在 Abaqus 软件中实现，并通过偏置拉伸实验进行了验证。

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