Advanced characterization of thermal degradation mechanisms in carbon fibre-reinforced polymer composites under continuous wave laser irradiation

IF 8.1 2区材料科学 Q1 ENGINEERING, MANUFACTURING

Composites Part A: Applied Science and Manufacturing Pub Date : 2025-02-19 DOI:10.1016/j.compositesa.2025.108817

Max Mammone , Jojibabu Panta , Richard P. Mildren , John Wang , Juan Escobedo-Diaz , Lance Mcgarva , Mathew Ibrahim , Adam Sharp , Richard Yang , Y.X. Zhang

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Abstract

This study provides a detailed and comprehensive analysis of the effects of laser power and beam diameter on the thermal damage characteristics of carbon fibre-reinforced polymer (CFRP) composites, aiming to uncover the underlying damage mechanisms using advanced characterization techniques. Continuous wave laser irradiation was performed with beam diameters of 3.18 mm and 5.70 mm at varying power levels up to 365 W to evaluate the influence of laser parameters on CFRP damage. High-resolution thermal imaging captured temperature distributions on the CFRP surfaces, revealing complex interactions between laser parameters and resulting thermal damage. Quantitative ultrasonic C-scan imaging offered detailed insights into the extent and distribution of damage, elucidating the interplay between laser parameters and CFRP integrity. Results show that for the 3.18 mm beam diameter, perforation times significantly decreased from 46 s at 215 W to 7 s at 365 W. Simultaneously, the damaged area reduced from 1204 mm² (48.2 %) at 215 W to 372 mm² (14.9 %) at 365 W, indicating efficient material ablation. Conversely, for the 5.7 mm beam diameter, perforation times were considerably longer, ranging from 393 s at 215 W to 269 s at 365 W, while the damage area increased from 1299 mm² (52.0 %) to 1712 mm² (68.5 %), reflecting a broader heat-affected zone (HAZ) and more extensive thermal damage. Mass loss trends also varied, decreasing with higher power for the smaller beam diameter but increasing for the larger beam, highlighting contrasting ablation efficiencies and thermal effects. Micro-CT imaging revealed internal structural changes in the CFRP, confirming SEM observations that detailed surface morphology alterations under varying laser conditions. Infrared micro-spectroscopy beamline (IRM) analysis further uncovered chemical modifications and compositional changes induced by laser exposure, providing insights into degradation mechanisms and residual stresses within the composite matrix. These findings significantly enhance the understanding of thermal damage mechanisms in CFRP, offering valuable implications for aerospace and high-performance composite applications.

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本研究详细而全面地分析了激光功率和光束直径对碳纤维增强聚合物（CFRP）复合材料热损伤特性的影响，旨在利用先进的表征技术揭示潜在的损伤机制。连续波激光辐照的光束直径分别为 3.18 毫米和 5.70 毫米，功率水平各不相同，最高可达 365 瓦，以评估激光参数对 CFRP 损伤的影响。高分辨率热成像技术捕捉到了 CFRP 表面的温度分布，揭示了激光参数与热损伤之间复杂的相互作用。定量超声波 C 扫描成像提供了对损坏程度和分布的详细了解，阐明了激光参数与 CFRP 完整性之间的相互作用。结果表明，对于 3.18 毫米的光束直径，穿孔时间从 215 瓦时的 46 秒大幅减少到 365 瓦时的 7 秒。同时，受损面积从 215 瓦时的 1204 平方毫米（48.2%）减少到 365 瓦时的 372 平方毫米（14.9%），表明材料烧蚀效率高。相反，对于直径为 5.7 毫米的光束，穿孔时间要长得多，从 215 瓦时的 393 秒到 365 瓦时的 269 秒，而损坏面积则从 1299 平方毫米（52.0%）增加到 1712 平方毫米（68.5%），这反映出热影响区（HAZ）更宽，热损坏范围更大。质量损失的趋势也各不相同，较小光束直径的质量损失随功率的增加而减少，而较大光束的质量损失则随功率的增加而增加，这凸显了截然不同的烧蚀效率和热效应。显微计算机断层扫描成像显示了 CFRP 的内部结构变化，证实了扫描电子显微镜的观察结果，即在不同激光条件下表面形态的详细变化。红外微光谱光束线（IRM）分析进一步揭示了激光照射引起的化学修饰和成分变化，为了解复合材料基体内的降解机制和残余应力提供了线索。这些发现大大加深了对 CFRP 热损伤机制的理解，为航空航天和高性能复合材料应用提供了宝贵的启示。

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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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.