Weld-line strength prediction for glass fiber reinforced polyamide-6 material through integrative simulation and its experimental validation

Journal of Thermoplastic Composite Materials Pub Date : 2023-11-16 DOI:10.1177/08927057231216747

G. Jadhav, V. Gaval

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Abstract

Injection molding is one of the preliminary production methods for plastic components. Typically, injection molding Moldflow simulations predicts potential issues like air void, weld-line, warpage etc. This work focuses on weld-line defect, which occurs when two or more flow fronts are meets each other during filling of the cavity. Most of the commercial algorithms are based on isotropic and homogeneous material assumptions however plastic materials are anisotropic and heterogeneous in nature. Therefore, accuracy with isotropic solvers may vary with actual reality. To consider material anisotropy and heterogeneous nature of the material, an integrative simulation is advantageous technology which gives more realistic results. A unique approach of integrative simulations has been used in this work to predict the strength of the weld-line as there is no direct standard procedure or software available to get weld-line strength. Moldflow simulation is performed on specially designed plaque wherein the weld-line is reproduced considering 30% glass-filled polyamide-6 material. The new material model is developed by mapping the structural model of tensile specimens on the Moldflow simulated plaque with integrative mapping approach. The mapped model considers fiber orientation and weld-line characteristics of the material which is then solved in the Abaqus structural solver. Experimental validation is performed by manufacturing of weld-line plaques, specimen preparation, and experimental testing. The results correlation is done for an isotropic and anisotropic material model with experimental results. The correlation study shows, a significant difference in results for isotropic simulation and integrative anisotropic simulations. The failure pattern and load-displacement behavior of integrative simulation is close match with experimental results with minimum 93% accuracy.

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通过综合模拟及其实验验证预测玻璃纤维增强聚酰胺-6 材料的焊接线强度

注塑成型是塑料部件的初步生产方法之一。通常，注塑成型 Moldflow 模拟可预测潜在的问题，如气隙、焊缝、翘曲等。这项工作的重点是焊缝缺陷，当两个或多个流动前沿在填充型腔过程中相遇时，就会出现焊缝缺陷。大多数商业算法都基于各向同性和均质材料假设，但塑料材料本质上是各向异性和异质的。因此，各向同性求解器的精度可能与实际情况不同。为了考虑材料的各向异性和异质性，综合模拟是一种有利的技术，它能提供更真实的结果。由于没有直接获得焊缝强度的标准程序或软件，本研究采用了一种独特的综合模拟方法来预测焊缝强度。Moldflow 模拟是在专门设计的牌坊上进行的，其中的焊接线是根据 30% 的玻璃填充聚酰胺-6 材料进行再现的。新的材料模型是通过综合映射方法将拉伸试样的结构模型映射到 Moldflow 模拟斑块上而建立的。映射模型考虑了材料的纤维取向和焊缝特征，然后在 Abaqus 结构求解器中求解。实验验证通过制造焊缝斑块、制备试样和实验测试来进行。各向同性和各向异性材料模型的结果与实验结果进行了相关性分析。相关研究表明，各向同性模拟和各向异性综合模拟的结果存在显著差异。综合模拟的破坏模式和载荷-位移行为与实验结果非常接近，精确度至少达到 93%。

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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Journal of Thermoplastic Composite Materials

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