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用于利用扭转超声导波对管道内缺陷进行车载定位的智能结构健康监测(SHM)系统。

Smart structural health monitoring (SHM) system for on-board localization of defects in pipes using torsional ultrasonic guided waves.

作者信息

Patil Sheetal, Banerjee Sauvik, Tallur Siddharth

机构信息

Department of Electrical Engineering (EE), IIT Bombay, Mumbai, 400076, India.

Department of Civil Engineering (CE), IIT Bombay, Mumbai, 400076, India.

出版信息

Sci Rep. 2024 Oct 18;14(1):24455. doi: 10.1038/s41598-024-76236-w.

DOI:10.1038/s41598-024-76236-w
PMID:39424967
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11489652/
Abstract

Most reported research for monitoring health of pipelines using ultrasonic guided waves (GW) typically utilize bulky piezoelectric transducer rings and laboratory-grade ultrasonic non-destructive testing (NDT) equipment. Consequently, the translation of these approaches from laboratory settings to field-deployable systems for real-time structural health monitoring (SHM) becomes challenging. In this work, we present an innovative algorithm for damage identification and localization in pipes, implemented on a compact FPGA-based smart GW-SHM system. The custom-designed board, featuring a Xilinx Artix-7 FPGA and front-end electronics, is capable of actuating the PZT thickness shear mode transducers, data acquisition and recording from PZT sensors and generating a damage index (DI) map for localizing the damage on the structure. The algorithm is a variation of the common source method adapted for cylindrical geometry. The utility of the algorithm is demonstrated for detection and localization of defects such as notch and mass loading on a steel pipe, through extensive finite element (FE) method simulations. Experimental results obtained using a C-clamp for applying mass loading on the pipe show good agreement with the FE simulations. The localization error values for experimental data analysed using C code on a processor implemented on the FPGA are consistent with algorithm results generated on a computer running Python code. The system presented in this study is suitable for a wide range of GW-SHM applications, especially in cost-sensitive scenarios that benefit from on-node signal processing over cloud-based solutions.

摘要

大多数报道的使用超声导波(GW)监测管道健康状况的研究通常采用笨重的压电换能器环和实验室级超声无损检测(NDT)设备。因此,将这些方法从实验室环境转化为用于实时结构健康监测(SHM)的现场可部署系统具有挑战性。在这项工作中,我们提出了一种用于管道损伤识别和定位的创新算法,该算法在基于紧凑型FPGA的智能GW-SHM系统上实现。定制设计的电路板以赛灵思Artix-7 FPGA和前端电子器件为特色,能够驱动PZT厚度剪切模式换能器,从PZT传感器进行数据采集和记录,并生成损伤指数(DI)图以定位结构上的损伤。该算法是适用于圆柱几何形状的共源方法的变体。通过广泛的有限元(FE)方法模拟,证明了该算法在检测和定位钢管上的缺口和质量加载等缺陷方面的实用性。使用C形夹对管道施加质量加载获得的实验结果与有限元模拟结果吻合良好。在FPGA上实现的处理器上使用C代码分析实验数据的定位误差值与在运行Python代码的计算机上生成的算法结果一致。本研究中提出的系统适用于广泛的GW-SHM应用,特别是在成本敏感的场景中,这些场景受益于基于节点的信号处理而非基于云的解决方案。

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