Prediction of transverse tensile strength of in-situ-consolidated Carbon/PEEK thermoplastic composite material based on micromechanical modeling and simulation

IF 8.1 2区材料科学 Q1 ENGINEERING, MANUFACTURING

Composites Part A: Applied Science and Manufacturing Pub Date : 2025-05-26 DOI:10.1016/j.compositesa.2025.109062

Emad Pourahmadi , Farjad Shadmehri , Rajamohan Ganesan

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Abstract

Thermoplastic composite laminates have emerged as a compelling alternative to thermoset laminates for primary aerospace applications, following the industrial development of automated manufacturing technologies, such as the Automated Fiber Placement (AFP) process. The present research aims to predict the transverse tensile strength of in-situ-consolidated Carbon/PEEK thermoplastic composite material, considering inherent variations caused by the AFP process in fiber volume fraction, void content, interlaminar resin pocket and degree of crystallinity. To achieve this, two-dimensional Representative Volume Elements (RVEs) with randomly distributed fibers were developed at the micro-scale level. The Drucker-Prager model, combined with a ductile failure criterion, was used to capture the plastic behavior and damage accumulation in the PEEK resin during the numerical analysis. In order to acquire the necessary data for micromechanical modeling and analysis, two sets of specimens, manufactured using AFP in-situ consolidation and autoclave re-consolidation techniques, underwent micrographic examination and thermoanalytical Differential Scanning Calorimetry (DSC) analysis. The results reveal that AFP in-situ consolidation can reduce the transverse tensile strength of Carbon/PEEK thermoplastic composite material up to approximately 44%, compared to the autoclave re-consolidation technique. Due to the lack of experimental data caused by warpage occurring in the manufactured laminate in the absence of a heated mandrel, the present work proposes a simulation methodology to predict the transverse tensile strength resulting from the in-situ consolidation process. This crucial difference in strength values, most notably in the transverse direction, must be carefully considered in finite element analyses, analytical evaluations, and design procedures involving AFP-manufactured thermoplastic composite laminates and structures.

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基于微力学建模与仿真的原位固结碳/PEEK热塑性复合材料横向抗拉强度预测

随着自动化制造技术的工业发展，如自动纤维铺放（AFP）工艺，热塑性复合材料层压板已成为热固性层压板在主要航空航天应用中的一个令人信服的替代品。本研究旨在预测原位固结碳/PEEK热塑性复合材料的横向拉伸强度，考虑AFP工艺对纤维体积分数、空隙含量、层间树脂袋和结晶度的固有变化。为了实现这一目标，在微观尺度上开发了具有随机分布纤维的二维代表性体积单元（RVEs）。采用Drucker-Prager模型，结合延性破坏准则，对聚醚醚酮树脂的塑性行为和损伤累积进行了数值分析。为了获得微观力学建模和分析所需的数据，采用AFP原位固结和高压釜再固结技术制造的两组试样进行了显微检查和热分析差示扫描量热法（DSC）分析。结果表明，与热压釜再固结技术相比，原位固结可使碳/PEEK热塑性复合材料的横向拉伸强度降低约44%。由于缺乏在没有加热芯棒的情况下由制造的层压板发生翘曲引起的实验数据，本工作提出了一种模拟方法来预测原位固结过程产生的横向抗拉强度。在涉及afp制造的热塑性复合材料层压板和结构的有限元分析、分析评估和设计过程中，必须仔细考虑这种强度值的关键差异，尤其是在横向上。

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来源期刊

Composites Part A: Applied Science and Manufacturing 工程技术-材料科学：复合

CiteScore

15.20

自引率

5.70%

发文量

492

审稿时长

30 days

期刊介绍： Composites Part A: Applied Science and Manufacturing is a comprehensive journal that publishes original research papers, review articles, case studies, short communications, and letters covering various aspects of composite materials science and technology. This includes fibrous and particulate reinforcements in polymeric, metallic, and ceramic matrices, as well as 'natural' composites like wood and biological materials. The journal addresses topics such as properties, design, and manufacture of reinforcing fibers and particles, novel architectures and concepts, multifunctional composites, advancements in fabrication and processing, manufacturing science, process modeling, experimental mechanics, microstructural characterization, interfaces, prediction and measurement of mechanical, physical, and chemical behavior, and performance in service. Additionally, articles on economic and commercial aspects, design, and case studies are welcomed. All submissions undergo rigorous peer review to ensure they contribute significantly and innovatively, maintaining high standards for content and presentation. The editorial team aims to expedite the review process for prompt publication.