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基于贝叶斯盲源分离的高速列车轮缘小缺陷的路边检测

Wayside Detection of Wheel Minor Defects in High-Speed Trains by a Bayesian Blind Source Separation Method.

机构信息

Hong Kong Branch of the National Rail Transit Electrification and Automation Engineering Technology Research Center, Hong Kong, China.

Department of Civil and Environmental Engineering, The Hong Kong Polytechnic University, Hung Hom, Kowloon, Hong Kong, China.

出版信息

Sensors (Basel). 2019 Sep 14;19(18):3981. doi: 10.3390/s19183981.

DOI:10.3390/s19183981
PMID:31540129
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6766959/
Abstract

For high-speed trains, out-of-roundness (OOR)/defects on wheel tread with small radius deviation may suffice to give rise to severe damage on both vehicle components and track structure when they run at high speeds. It is thus highly desirable to detect the defects in a timely manner and then conduct wheel re-profiling for the defective wheels. This paper presents a wayside fiber Bragg grating (FBG)-based wheel condition monitoring system which can detect wheel tread defects online during train passage. A defect identification algorithm is developed to identify potential wheel defects with the monitoring data of rail strain response collected by the devised system. In view that minor wheel defects can only generate anomalies with low amplitude compared with the wheel load effect, advanced signal processing methods are needed to extract the defect-sensitive feature from the monitoring data. This paper explores a Bayesian blind source separation (BSS) method to decompose the rail response signal and to obtain the component that contains defect-sensitive features. After that, the potential defects are identified by analyzing anomalies in the time history based on the Chauvenet's criterion. To verify the proposed defect detection method, a blind test is conducted using a new train equipped with defective wheels. The results show that all the defects are identified and they concur well with offline wheel radius deviation measurement results. Minor defects with a radius deviation of only 0.06 mm are successfully detected.

摘要

对于高速列车,车轮踏面的椭圆度(OOR)/小半径偏差缺陷在高速运行时足以对车辆部件和轨道结构造成严重损坏。因此,及时发现缺陷并对有缺陷的车轮进行轮辋再成型是非常必要的。本文提出了一种基于光纤布拉格光栅(FBG)的车轮状态监测系统,可在列车通过时在线检测车轮踏面缺陷。开发了一种缺陷识别算法,利用所设计系统采集的轨道应变响应监测数据来识别潜在的车轮缺陷。由于与车轮载荷效应相比,较小的车轮缺陷只会产生幅度较低的异常,因此需要先进的信号处理方法从监测数据中提取缺陷敏感特征。本文探讨了一种贝叶斯盲源分离(BSS)方法来分解轨道响应信号,并获得包含缺陷敏感特征的分量。然后,根据 Chauvenet 准则,通过分析时间历史上的异常来识别潜在的缺陷。为了验证所提出的缺陷检测方法,对装有缺陷车轮的新列车进行了盲测试验。结果表明,所有缺陷均被识别,且与离线车轮半径偏差测量结果吻合良好。成功检测到半径偏差仅为 0.06mm 的小缺陷。

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本文引用的文献

1
Computer vision based method and system for online measurement of geometric parameters of train wheel sets.基于计算机视觉的列车轮对几何参数在线测量方法及系统。
Sensors (Basel). 2012;12(1):334-46. doi: 10.3390/s120100334. Epub 2011 Dec 30.
2
Fast and robust fixed-point algorithms for independent component analysis.用于独立成分分析的快速且稳健的定点算法。
IEEE Trans Neural Netw. 1999;10(3):626-34. doi: 10.1109/72.761722.
3
EEGLAB: an open source toolbox for analysis of single-trial EEG dynamics including independent component analysis.
Sensors (Basel). 2023 Feb 25;23(5):2558. doi: 10.3390/s23052558.
4
Detection of Tram Wheel Faults Using MEMS-Based Sensors.使用基于微机电系统(MEMS)的传感器检测电车车轮故障。
Sensors (Basel). 2022 Aug 24;22(17):6373. doi: 10.3390/s22176373.
5
Application of Moire Profilometry in Three-Dimensional Profile Reconstruction of Key Parts in Railway.云纹法测量在铁路关键部位三维轮廓重建中的应用。
Sensors (Basel). 2022 Mar 24;22(7):2498. doi: 10.3390/s22072498.
6
Identification of Sleeper Support Conditions Using Mechanical Model Supported Data-Driven Approach.使用基于机械模型支持的数据驱动方法识别睡眠支撑条件。
Sensors (Basel). 2021 May 22;21(11):3609. doi: 10.3390/s21113609.
7
Test and Study of Pipe Pile Penetration in Cohesive Soil Using FBG Sensing Technology.基于光纤光栅传感技术的管桩在粘性土中贯入特性的试验与研究
Sensors (Basel). 2020 Mar 30;20(7):1934. doi: 10.3390/s20071934.
8
Identification of Temperature-Induced Deformation for HSR Slab Track Using Track Geometry Measurement Data.利用轨道几何测量数据识别高速铁路板式轨道温度引起的变形。
Sensors (Basel). 2019 Dec 10;19(24):5446. doi: 10.3390/s19245446.
EEGLAB:一个用于分析单次试验脑电图动态(包括独立成分分析)的开源工具箱。
J Neurosci Methods. 2004 Mar 15;134(1):9-21. doi: 10.1016/j.jneumeth.2003.10.009.