The impact of thermal treatment parameters on the preservation of carbon fiber mechanical properties after reclamation

Marina Corvo Alguacil , Kentaro Umeki , Sergejs Gaidukovs , Anda Barkāne , Shujie You , Roberts Joffe
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Abstract

Carbon fiber, despite its exceptional properties, remains underutilized due to monetary and environmental concerns. Concurrently, the imminent challenge associated with rising quantities of End-of-Life CFRP (carbon fiber reinforced polymer) demands the further development of recycling strategies. This study focuses on optimizing the recycling process parameters of pyrolysis and oxidation thermal treatment to maximize the retention of mechanical properties in the recycled fibers in the shortest process time. To assess the result of the pyrolysis, single fiber tensile tests were executed to measure strength and stiffness. Additionally, microscopy and spectroscopy studies were carried out to evaluate fiber geometry as well as surface quality. At the laboratory scale, experiments demonstrated that the combination of pyrolysis and oxidation yields clean, reusable fibers with mechanical properties suitable for secondary applications. The influence of various treatment parameters on the strength and stiffness of the recycled fibers was explored, establishing a clear correlation. The outcome is a set of optimized parameters that contribute to mechanical property retention, including a novel recycling method that allows for reduced processing times, as short as 10 min. This work paves the way for a more eco-friendly and cost-effective approach to harnessing the potential of carbon fiber in a wide range of applications while mitigating environmental concerns associated with landfill disposal.
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热处理参数对再生后碳纤维机械性能保持的影响
尽管碳纤维具有优异的性能,但由于资金和环境问题,其利用率仍然很低。同时,随着报废 CFRP(碳纤维增强聚合物)数量的不断增加,迫在眉睫的挑战要求进一步制定回收战略。本研究的重点是优化热解和氧化热处理的回收工艺参数,以便在最短的工艺时间内最大限度地保留回收纤维的机械性能。为评估热解结果,对单根纤维进行了拉伸试验,以测量强度和刚度。此外,还进行了显微镜和光谱研究,以评估纤维的几何形状和表面质量。实验室规模的实验表明,热解和氧化相结合可产生清洁、可重复使用的纤维,其机械性能适合二次应用。实验还探讨了各种处理参数对再生纤维强度和刚度的影响,并建立了明确的相关性。研究结果是一套有助于保持机械性能的优化参数,包括一种可缩短处理时间(短至 10 分钟)的新型回收方法。这项工作为采用更环保、更具成本效益的方法利用碳纤维在广泛应用中的潜力铺平了道路,同时减轻了与垃圾填埋处理相关的环境问题。
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来源期刊
Current Research in Green and Sustainable Chemistry
Current Research in Green and Sustainable Chemistry Materials Science-Materials Chemistry
CiteScore
11.20
自引率
0.00%
发文量
116
审稿时长
78 days
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