A Machine Learning Based-Guided Wave Approach for Damage Detection and Assessment in Composite Overwrapped Pressure Vessels

Research and Review Journal of Nondestructive Testing Pub Date : 2023-08-01 DOI:10.58286/28079

A. Charmi, S. Mustapha, Bengisu Yilmaz, J. Heimann, J. Prager

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Abstract

The applications of composite overwrapped pressure vessels (COPVs) in extreme conditions, such as storing hydrogen gases at very high pressure, impose new requirements related to the system's integrity and safety. The development of a structural health monitoring (SHM) system that allows for continuous monitoring of the COPVs provides rich information about the structural integrity of the component. Furthermore, the collected data can be used for different purposes such as increasing the periodic inspection intervals, providing a remaining lifetime prognosis, and also ensuring optimal operating conditions. Ultimately this information can be complementary to the development of the envisioned digital twin of the monitored COPVs. Guided waves (GWs) are preferred to be used in continuous SHM given their ability to travel in complex structures for long distances. However, obtained GW signals are complex and require advanced processing techniques. Machine learning (ML) is increasingly utilized as the main part of the processing pipeline to automatically detect anomalies in the system's integrity. Hence, in this study, we are scrutinizing the potential of using ML to provide continuous monitoring of COPVs based on ultrasonic GW data. Data is collected from a network of sensors consisting of fifteen Piezoelectric (PZT) wafers that were surface mounted on the COPV. Two ML algorithms are used in the automated evaluation procedure (i) a long short-term memory (LSTM) autoencoder for anomaly detection (defects/impact), and (ii) a convolutional neural network (CNN) model for feature extraction and classification of the artificial damage sizes and locations. Additional data augmentation steps are introduced such as modification and addition of random noise to original signals to enhance the model's robustness to uncertainties. Overall, it was shown that the ML algorithms used were able to detect and classify the simulated damage with high accuracy.

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基于机器学习的复合材料包覆压力容器损伤检测与评估导波方法

复合材料包覆压力容器(copv)在极端条件下的应用，例如在非常高的压力下储存氢气，对系统的完整性和安全性提出了新的要求。结构健康监测(SHM)系统的开发允许对copv进行连续监测，从而提供有关组件结构完整性的丰富信息。此外，收集到的数据可以用于不同的目的，如增加定期检查间隔，提供剩余寿命预测，并确保最佳的操作条件。最终，这些信息可以补充开发所监测的copv的预期数字孪生体。考虑到导波在复杂结构中长距离传播的能力，导波被首选用于连续SHM。然而，获得的GW信号非常复杂，需要先进的处理技术。机器学习(ML)越来越多地被用作处理管道的主要部分，以自动检测系统完整性中的异常。因此，在本研究中，我们正在仔细研究使用ML提供基于超声GW数据的copv连续监测的潜力。数据收集自一个传感器网络，该网络由15个压电(PZT)晶圆组成，这些晶圆表面安装在COPV上。在自动评估过程中使用了两种机器学习算法(i)用于异常检测(缺陷/影响)的长短期记忆(LSTM)自动编码器，以及(ii)用于特征提取和人工损伤大小和位置分类的卷积神经网络(CNN)模型。为了提高模型对不确定性的鲁棒性，引入了对原始信号进行修正和添加随机噪声等额外的数据增强步骤。总体而言，研究表明所使用的机器学习算法能够以较高的精度检测和分类模拟损伤。

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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Research and Review Journal of Nondestructive Testing

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