Non-Contact Geomagnetic Localization of Pipeline Defects Using Empirical Mode Decomposition and Magnetic Gradient Tensor

Volume 1: Pipeline and Facilities Integrity Pub Date : 2018-09-24 DOI:10.1115/IPC2018-78258

Tao Zhang, Xinhua Wang, Yingchun Chen, Z. Ullah, Yizhen Zhao

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Abstract

Non-contact geomagnetic anomaly detection, as one of passive non-destructive testing (NDT) techniques, can be used to locate pipeline defects, while its accuracy is affected by random noise and detection orientation. In order to extract effective geomagnetic anomaly signals of pipeline defects, a method based on empirical mode decomposition (EMD) and magnetic gradient tensor was studied. In order to filter random noise, EMD was performed to self-adaptively decompose magnetic field signals into a series of intrinsic mode functions (IMFs), and then Hurst exponent was implemented to exclude false modes; The calculation method of magnetic gradient tensor modulus (MGTM) was proposed to obtain precise defect locations according to tensor symmetry; Subsequently, the remote pipeline defect model was built based on the magnetic dipole theory, and the relationship between detection orientation and MGTM was discussed. The experimental results showed that the proposed method could realize high precision and reliable non-contact geomagnetic localization of pipeline defects.

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基于经验模态分解和磁梯度张量的管道缺陷非接触地磁定位

非接触地磁异常检测作为被动无损检测技术的一种，可用于管道缺陷的定位，但其精度受随机噪声和检测方向的影响。为了提取有效的管道缺陷地磁异常信号，研究了一种基于经验模态分解(EMD)和磁梯度张量的方法。为了滤除随机噪声，采用EMD将磁场信号自适应分解为一系列内禀模态函数(IMFs)，然后利用Hurst指数剔除假模态;提出了磁梯度张量模(MGTM)的计算方法，根据张量对称性获得精确的缺陷位置;随后，基于磁偶极子理论建立了管道远程缺陷模型，并讨论了检测方向与MGTM之间的关系。实验结果表明，该方法能够实现管道缺陷的高精度、可靠的非接触地磁定位。

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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Volume 1: Pipeline and Facilities Integrity

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