Magnetic Barkhausen Noise Technique for Fatigue Detection and Classification in Martensitic Stainless-Steel

Bharath Basti Shenoy, Zi Li, L. Udpa, S. Udpa, Y. Deng, T. Seuaciuc-Osório
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Abstract

Stainless steel is used in many applications because of its excellent mechanical properties at elevated temperatures. Material fatigue is a major problem in steel structures and can cause catastrophic damage resulting in significant economic consequences. Conventional nondestructive evaluation techniques can detect macro defects, but do not perform well when it comes to material degradation due to fatigue, which happens at a microstructure level. It is well known that stress applied on a material will have an impact on the microstructure and produces a change in the magnetic properties of the material. Hence magnetic nondestructive evaluation techniques that are sensitive to changes in magnetic properties play a major role in the early-stage fatigue detection, i.e., before the macro crack initiates. This paper introduces the Magnetic barkhausen noise technique to garner information about fatigue state of the material under test. K-medoids clustering algorithm and genetic optimization algorithm are used to classify the stainless-samples into fatigue categories. Initial results prove that the martensitic grade stainless-steel samples in different stages of fatigue can be classified into broad fatigue categories, i.e., low fatigue, mid fatigue and high fatigue based on the remaining useful life of the sample.
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磁巴克豪森噪声技术在马氏体不锈钢疲劳检测与分类中的应用
由于不锈钢在高温下具有优异的机械性能,因此在许多应用中得到了应用。材料疲劳是钢结构中的一个主要问题,它会造成灾难性的破坏,造成重大的经济后果。传统的无损检测技术可以检测宏观缺陷,但在微观结构水平上由于疲劳引起的材料退化方面表现不佳。众所周知,施加在材料上的应力会对材料的微观结构产生影响,并使材料的磁性发生变化。因此,对磁性能变化敏感的磁性无损评价技术在早期疲劳检测中起着重要作用,即在宏观裂纹开始之前。本文介绍了磁巴克豪森噪声技术来获取被测材料的疲劳状态信息。采用K-medoids聚类算法和遗传优化算法对不锈钢试样进行疲劳分类。初步结果表明,根据试样的剩余使用寿命,可将处于不同疲劳阶段的马氏体级不锈钢试样分为低疲劳、中疲劳和高疲劳三大类。
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CiteScore
3.80
自引率
9.10%
发文量
25
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