Abstract
Stress is the crucial factor of ferromagnetic material failure origin. However, the nondestructive test methods to analyze the ferromagnetic material properties’ inhomogeneity on the microscopic scale with stress have not been obtained so far. In this study, magnetic Barkhausen noise (MBN) signals on different silicon steel sheet locations under in situ tensile tests were detected by a high-spatial-resolution magnetic probe. The domain-wall (DW) motion, grain, and grain boundary were detected using a magneto-optical Kerr (MOKE) image. The time characteristic of DW motion and MBN signals on different locations was varied during elastic deformation. Therefore, a time-response histogram is proposed in this work to show different DW motions inside the grain and around the grain boundary under low tensile stress. In order to separate the variation of magnetic properties affected by the grain and grain boundary under low tensile stress corresponding to MBN excitation, time-division was carried out to extract the root-mean-square (RMS), mean, and peak in the optimized time interval. The time-response histogram of MBN evaluated the silicon steel sheet’s inhomogeneous material properties, and provided a theoretical and experimental reference for ferromagnetic material properties under stress.
Highlights
The Relationship between the Time-Response Histogram and DW Motion on the Grain and tensile stress and without tensile stress was determined to reduce the difference of the features in the optimized time intervals
To analyze the influence of grain interior and grain boundary on the inhomogeneous magnetic properties, the results of the time-response histogram were investigated to analyze the variation of magnetic Barkhausen noise (MBN) at different locations
Based on the observation of grain distribution and MBN of silicon steel, the timeresponse histogram was used to investigate the influence of the grain and grain boundary on the micromagnetic properties under tensile stress
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Stresses play a pivotal role in determining the durability and service life of components. Jun et al reported that components are vulnerable because of crack initiation caused by the generation of high tensile stresses [4]. Lee et al assessed the fatigue life of a welded repaired rail based on the welding process and contact stresses [5]
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