Analysis and Optimization Design of Rectangular Coil as Uniform Current Source

2018 IEEE Far East NDT New Technology & Application Forum (FENDT) Pub Date : 2018-07-01 DOI:10.1109/FENDT.2018.8681954

Peng Gao, Xuan Wang, Weifei Niu, Yang Yang

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Abstract

The axis of the rectangular coil is parallel to the surface of the conductor under test, and a uniform eddy current field can be generated on the surface of the conductor. This structure is widely used in eddy current testing. In this paper, a finite element simulation model of a uniform eddy current rectangular coil was built using finite element method (FEM) to obtain the sensitivity of a uniform eddy current rectangular coil with different heights, lengths, widths, and thicknesses. The relationship between the geometric dimensions and sensitivity was obtained by function fitting. Through simulation analysis, it was found that increasing coil height and length can increase coil sensitivity. Keeping the coil turns per unit area constant, increasing the thickness of the coil increases the coil’s sensitivity. Increasing the width of the coil, the sensitivity of the sensor increases first and then decreases, so there is a maximum range. The methods and conclusions presented in this paper provide a reference for the optimal design of uniform eddy current rectangular coils.

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矩形线圈作为均匀电流源的分析与优化设计

矩形线圈的轴线平行于被测导体表面，可在导体表面产生均匀的涡流场。该结构广泛应用于涡流检测中。本文采用有限元法建立了均匀涡流矩形线圈的有限元仿真模型，得到了不同高度、长度、宽度和厚度的均匀涡流矩形线圈的灵敏度。通过函数拟合得到几何尺寸与灵敏度之间的关系。通过仿真分析，发现增大线圈高度和长度可以提高线圈的灵敏度。保持单位面积的线圈匝数不变，增加线圈的厚度可以增加线圈的灵敏度。增加线圈的宽度，传感器的灵敏度先增加后降低，所以有一个最大范围。所得方法和结论可为均匀涡流矩形线圈的优化设计提供参考。

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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2018 IEEE Far East NDT New Technology & Application Forum (FENDT)

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