Interrogation system for passive solid-state sensors embedded in composites

Proceedings: Electrical Insulation Conference and Electrical Manufacturing and Coil Winding Conference (Cat. No.01CH37264) Pub Date : 2001-10-16 DOI:10.1109/EEIC.2001.965751

K. A. Lavere, L. Thompson

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Abstract

Development of passive solid-state ferromagnetic sensors suitable for assessing damage accumulation in composite materials requires an accurate, reproducible detection technique. The solid state sensors gradually transform from a paramagnetic phase to a ferromagnetic phase as a function of applied strain. The irreversible and strain dependent formation of ferromagnetic material passively provides a magnetic signature useful in nondestructively assessing peak strain exposure. This peak strain signature can be used to identify and quantitatively estimate the degree or extent of accumulated composite material damage. Embedded sensors were continuous 254-/spl mu/m diameter wires positioned beneath the first or second surface ply along the longitudinal axes of tensile specimens. Single embedded wire sensor configurations were evaluated. This paper discusses the development and results obtained for a giant magneto-resistive (GMR) sensor detection system for measuring the ferromagnetic response of the sensor wires after strain-controlled tensile testing. Tensile testing was done at levels ranging from 0-4% total strain.

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嵌入复合材料的无源固态传感器探测系统

开发适用于评估复合材料损伤累积的无源固态铁磁传感器需要一种精确的、可重复的检测技术。随着外加应变的变化，固态传感器逐渐从顺磁相转变为铁磁相。铁磁材料的不可逆和应变依赖的被动形成提供了一个有用的无损评估峰值应变暴露的磁签名。该峰值应变特征可用于识别和定量估计复合材料累积损伤的程度或范围。嵌入的传感器是直径为254-/spl mu/m的连续导线，沿着拉伸试样的纵轴放置在第一层或第二层表面下。评估了单个嵌入式导线传感器的配置。本文讨论了一种用于测量传感器导线在应变控制拉伸试验后的铁磁响应的巨磁电阻(GMR)传感器检测系统的研制和结果。拉伸试验在0-4%的总应变范围内进行。

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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Proceedings: Electrical Insulation Conference and Electrical Manufacturing and Coil Winding Conference (Cat. No.01CH37264)

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