J. Zhang, Chaojie Hu, Jian-jun Yan, Yue Hu, Yang Gao, F. Xuan
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引用次数: 0
摘要
导波对结构变化的灵敏度高,传播距离远,是结构健康监测的关键无损技术。然而,为了达到较高的损伤定位精度,检测算法通常需要大量的样本和数千次的迭代。针对这一问题,本文采用由一维(1D)和二维(2D)卷积层组成的可解释卷积神经网络(eXplainable Convolutional neural network for Multivariate time series classification, XCM),在有限的训练集下实现压力容器的高精度损伤定位。通过进一步优化网络参数和网络结构,大大缩短了训练时间,进一步提高了准确率。优化后的XCM在小样本(训练集/验证集/测试集=23/2/25)和低训练次数(100次以下)下,将损伤定位精度从95.5%提高到98%,表明XCM在压力容器损伤定位分类中具有很大的优势。基于导波的损伤检测技术在结构健康监测中的应用潜力。
Guided Wave Damage Location of Pressure Vessel Based On Optimized XCM Neural Network
Guided wave is a key nondestructive technique for structural health monitoring due to its high sensitivity to structural changes and long propagation distance. However, to achieve high accuracy for damage location, large quantity of samples and thousands of iterations are typically needed for detection algorithms. To address this, in this paper, an eXplainable Convolutional neural network for Multivariate time series classification (XCM) is adopted, which is composed of one-dimensional (1D) and two-dimensional (2D) convolution layers to achieve high accuracy damage location on pressure vessels with limited training sets. By further optimizing the network parameters and network structure, the training time is greatly reduced and the accuracy is further improved. The optimized XCM improves the damage location precision from 95.5% to 98% with small samples (training set/validation set/testing set=23/2/25) and low training epochs (under 100 epochs), suggesting that the XCM has great advantages in pressure vessel's damage location classification. its potential for guided wave-based damage detection technique in structural health monitoring.
期刊介绍:
The Journal of Pressure Vessel Technology is the premier publication for the highest-quality research and interpretive reports on the design, analysis, materials, fabrication, construction, inspection, operation, and failure prevention of pressure vessels, piping, pipelines, power and heating boilers, heat exchangers, reaction vessels, pumps, valves, and other pressure and temperature-bearing components, as well as the nondestructive evaluation of critical components in mechanical engineering applications. Not only does the Journal cover all topics dealing with the design and analysis of pressure vessels, piping, and components, but it also contains discussions of their related codes and standards.
Applicable pressure technology areas of interest include: Dynamic and seismic analysis; Equipment qualification; Fabrication; Welding processes and integrity; Operation of vessels and piping; Fatigue and fracture prediction; Finite and boundary element methods; Fluid-structure interaction; High pressure engineering; Elevated temperature analysis and design; Inelastic analysis; Life extension; Lifeline earthquake engineering; PVP materials and their property databases; NDE; safety and reliability; Verification and qualification of software.
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