Acoustic Emission Measurement and Location Analysis of Acoustic Emission Source for Superconducting Coil Quench During Training

Volume 1: Acoustics, Vibration, and Phononics Pub Date : 2022-10-30 DOI:10.1115/imece2022-91393

J. Hirokawa, O. Nishimura, Y. Hisakuni, A. Kano, Hideaki Uehara, T. Monda, K. Hirohata, Toshinobu Ito, Shohei Takami, T. Orikasa, Kiyokazu Sato

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Abstract

Acoustic emission (AE) measurement is a non-destructive testing method that can detect high-frequency elastic waves generated by mechanical events inside an object, and is able to localize the wave source by using multiple sensors. In order to determine the mechanism causing the quench phenomenon in superconducting coil, we applied the AE method to a small ellipse-shaped coil in a training experiment. Six AE sensors were installed on the coil surface before the coil was cooled to 4 K in a vacuum vessel and excited. The current to the coil was controlled to produce a gradual increase until the quench occurred. The entire training experiment ended after over 10 quenches and all AE events that occurred in each training cycle were measured. The location of the AE source inside the coil was calculated from the difference in arrival time between sensors, and the results were plotted on an expansion plan of the coil. High-amplitude AE events appeared in areas assumed to have sufficiently high internal stress to cause concentration of strain energy.

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训练过程中超导线圈淬火声发射测量及声发射源定位分析

声发射(AE)测量是一种无损检测方法，可以检测到物体内部机械事件产生的高频弹性波，并且可以通过使用多个传感器来定位波源。为了确定超导线圈中淬火现象产生的机理，在训练实验中对一个小椭圆型线圈进行了声发射实验。在线圈表面安装6个声发射传感器，然后将线圈在真空容器中冷却至4k并进行激励。对线圈的电流进行控制，使其逐渐增大，直到发生淬火。在10次以上淬火后结束整个训练实验，并测量每个训练周期内发生的所有AE事件。根据传感器之间到达时间的差异计算出线圈内声发射源的位置，并将结果绘制在线圈的扩展图上。高振幅声发射事件出现在假定具有足够高的内应力从而引起应变能集中的区域。

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: Acoustics, Vibration, and Phononics

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