In-Motion Railcar Wheel Inspection using Magnetostrictive EMATs

Anish Poudel, Borja Lopez, Syed Ali, Josh Bensur
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Abstract

Due to cyclic mechanical loading, railcar wheels are subject to the development of internal fatigue cracks in the rim underneath the tread surface. Off-line inspections are extremely laborious and require extended out-of-service time, and most existing in-line inspection systems that use conventional ultrasonics or electromagnetic acoustic transducer (EMAT) techniques have several drawbacks that limit their full-scale deployment in service. This paper discusses the work performed on the initial research and development of a proof-of-concept novel magnetostrictive EMAT sensor for in-motion railcar wheel inspection. Wheelsets with known internal discontinuities and a 3.7 m long panelized track were used to demonstrate the feasibility of the developed approach and methods. The results obtained from these tests have shown that the magnetostrictive EMAT sensor that generates 5 mm wavelength shear horizontal waves detects both surface defects and internal fatigue cracks with an excellent signal-to-noise ratio. Different wavelengths can also be added to the sensors to enhance or complement the detection of fatigue cracks at different depths. A total of four or five sensors located at standard concrete crosstie spacing along each rail would be able to provide complete coverage on wheels ranging from 711 to 965 mm in diameter with ±90° wheel coverage per sensor, and a theoretical inspection speed of 56 kph can be achieved using this approach.
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使用磁致伸缩 EMAT 对轨道车车轮进行动态检测
由于周期性的机械负载,轨道车车轮会在胎面下的轮辋中产生内部疲劳裂纹。离线检测非常费力,需要延长停用时间,而大多数现有的在线检测系统都采用传统的超声波或电磁声学传感器(EMAT)技术,这些技术存在一些缺陷,限制了其在服务中的全面应用。本文讨论了用于轨道车车轮在线检测的新型磁致伸缩 EMAT 传感器的初步研究和开发工作。使用已知内部不连续性的轮对和 3.7 米长的板式轨道来证明所开发的方法和手段的可行性。测试结果表明,磁致伸缩 EMAT 传感器能产生 5 毫米波长的水平剪切波,以出色的信噪比检测表面缺陷和内部疲劳裂纹。还可以在传感器上添加不同波长,以增强或补充对不同深度疲劳裂纹的检测。在每条钢轨的标准混凝土横梁间距上安装四到五个传感器,就能完全覆盖直径为 711 到 965 毫米的车轮,每个传感器的车轮覆盖范围为 ±90°,采用这种方法,理论检测速度可达 56 千米/小时。
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