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Acoustic emission-based damage pattern identification and residual strength prediction of glass-fiber reinforced polymers
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  • Xiheng Xu,
  • Xinyu Bi,
  • Zhuohan Li,
  • Yiliang You
Xiheng Xu
Beihang University School of Materials Science and Engineering
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Xinyu Bi
Beihang University School of Materials Science and Engineering
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Zhuohan Li
Beihang University School of Materials Science and Engineering
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Yiliang You
Beihang University School of Materials Science and Engineering

Corresponding Author:yyl@buaa.edu.cn

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Abstract

In this paper, the damage mechanisms and residual strength prediction models of unidirectional glass-fiber reinforced polymers are investigated by acoustic emission(AE) technique. The material exhibits three damage modes: matrix cracking, fiber fracture, and interface damage. A novel AE descriptor, amplitude/centroid frequency (ACF), is introduced to differentiate interface damage from other damage modes. Moreover, three signal types exhibit a strong clustering effect when correlated with ACF and average frequency. Microscopic damage mechanisms of the samples are observed using scanning electron microscopy and correlated with AE signals. The AE signals are analyzed using machine learning, and the clustering analysis results are used as a training set to obtain classification models using support vector machine (SVM) and K-nearest neighbor (KNN) methods. Leveraging the traditional mechanical regression analysis prediction model, the study achieves prediction of the material’s residual strength post-fatigue through improvement in AE cumulative counting. Additionally, optimization of prediction results can be achieved by a certain kind of signal after clustering. The combination of supervised learning and residual strength prediction models can realize the real-time classification of AE signals and apply them to the prediction of residual strength, which has a significant application value in real-time monitoring.
12 Oct 2024Submitted to Fatigue & Fracture of Engineering Materials & Structures
14 Oct 2024Submission Checks Completed
14 Oct 2024Assigned to Editor
30 Oct 2024Reviewer(s) Assigned
13 Nov 2024Review(s) Completed, Editorial Evaluation Pending
20 Nov 2024Editorial Decision: Revise Major