Remaining useful life prediction of flax fibre biocomposites under creep load by acoustic emission and deep learning

IF 8.1 2区材料科学 Q1 ENGINEERING, MANUFACTURING

Composites Part A: Applied Science and Manufacturing Pub Date : 2024-11-02 DOI:10.1016/j.compositesa.2024.108572

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引用次数: 0

Abstract

Natural fibre composites are increasingly explored for structural applications due to improvements in mechanical performance. For this, damage prognostics are crucial. We integrate acoustic emission (AE) and deep learning techniques to predict the remaining useful life of a flax fibre composite under long-term creep load. Derivatives of cumulative AE features with respect to time, such as cumulative hit and count rates, are introduced to reflect the performance degradation rate of the materials. These proposed features seem more relevant for creep lifespan than traditional AE features. Long short-term memory networks and temporal convolutional networks are adopted to estimate the composite’s remaining useful life. The two models' normalized root mean square errors are below 0.11, less than 20% of the error of a statistical Weibull-distribution benchmark model. Our study demonstrates that AE-based data-driven models can predict the performance degradation of composite materials subject to sustained load.

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利用声发射和深度学习预测蠕变载荷下亚麻纤维生物复合材料的剩余使用寿命

由于机械性能的提高，天然纤维复合材料在结构应用中的应用日益广泛。为此，损伤预报至关重要。我们整合了声发射（AE）和深度学习技术，以预测亚麻纤维复合材料在长期蠕变负载下的剩余使用寿命。我们引入了累积声发射特征相对于时间的衍生物，如累积命中率和计数率，以反映材料的性能退化率。与传统的 AE 特征相比，这些建议的特征似乎与蠕变寿命更相关。采用长短期记忆网络和时序卷积网络来估算复合材料的剩余使用寿命。这两个模型的归一化均方根误差低于 0.11，小于统计 Weibull 分布基准模型误差的 20%。我们的研究表明，基于 AE 的数据驱动模型可以预测承受持续载荷的复合材料的性能退化。

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.