New parameters in adaptive testing of ferromagnetic materials utilizing magnetic Barkhausen noise

A new method of magnetic Barkhausen noise (MBN) measurement and optimization of the measured data processing with respect to non-destructive evaluation of ferromagnetic materials was tested. Using this method we tried to found, if it is possible to enhance sensitivity and stability of measurement re...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2016-03, Vol.402, p.172-177
Main Authors: Pal'a, Jozef, Usak, Elemir
Format: Article
Language:English
Subjects:
Data processing
Ferromagnetic materials
Hysteresis loops
Magnetic adaptive testing
Magnetic Barkhausen noise
Magnetism
Mean square values
Nondestructive testing
Optimization
Plastic deformation
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Summary:A new method of magnetic Barkhausen noise (MBN) measurement and optimization of the measured data processing with respect to non-destructive evaluation of ferromagnetic materials was tested. Using this method we tried to found, if it is possible to enhance sensitivity and stability of measurement results by replacing the traditional MBN parameter (root mean square) with some new parameter. In the tested method, a complex set of the MBN from minor hysteresis loops is measured. Afterward, the MBN data are collected into suitably designed matrices and optimal parameters of MBN with respect to maximum sensitivity to the evaluated variable are searched. The method was verified on plastically deformed steel samples. It was shown that the proposed measuring method and measured data processing bring an improvement of the sensitivity to the evaluated variable when comparing with measuring traditional MBN parameter. Moreover, we found a parameter of MBN, which is highly resistant to the changes of applied field amplitude and at the same time it is noticeably more sensitive to the evaluated variable. •We test an adaptive magnetic Barkhausen noise method.•The method utilizes measuring a complex set of Barkhausen noise signals.•We define new matrices of parameters for this method.•The pulse density is highly resistant to changes in applied field amplitude.
ISSN:0304-8853
DOI:10.1016/j.jmmm.2015.11.064