Hysteresis model and statistical interpretation of energy losses in non-oriented steels

In this paper the hysteresis energy losses in two non-oriented industrial steels (M400-65A and M800-65A) were determined, by means of an efficient classical Preisach model, which is based on the Pescetti–Biorci method for the identification of the Preisach density. The excess and the total energy lo...

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Bibliographic Details
Published in:Physica. B, Condensed matter Condensed matter, 2016-04, Vol.486, p.12-16
Main Authors: Manescu, Veronica, Paltanea, Gheorghe, Gavrila, Horia
Format: Article
Language:English
Subjects:
Computation
Condensed matter
Density
Energy losses
Energy use
Hysteresis
Hysteresis losses
Loss separation concept
Magnetic object theory
Mathematical models
Non-oriented electrical steel
Polarization
Preisach model
Steels
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Summary:In this paper the hysteresis energy losses in two non-oriented industrial steels (M400-65A and M800-65A) were determined, by means of an efficient classical Preisach model, which is based on the Pescetti–Biorci method for the identification of the Preisach density. The excess and the total energy losses were also determined, using a statistical framework, based on magnetic object theory. The hysteresis energy losses, in a non-oriented steel alloy, depend on the peak magnetic polarization and they can be computed using a Preisach model, due to the fact that in these materials there is a direct link between the elementary rectangular loops and the discontinuous character of the magnetization process (Barkhausen jumps). To determine the Preisach density it was necessary to measure the normal magnetization curve and the saturation hysteresis cycle. A system of equations was deduced and the Preisach density was calculated for a magnetic polarization of 1.5T; then the hysteresis cycle was reconstructed. Using the same pattern for the Preisach distribution, it was computed the hysteresis cycle for 1T. The classical losses were calculated using a well known formula and the excess energy losses were determined by means of the magnetic object theory. The total energy losses were mathematically reconstructed and compared with those, measured experimentally.
ISSN:0921-4526
1873-2135
DOI:10.1016/j.physb.2015.09.004