On the Energy-Based Variational Model for Vector Magnetic Hysteresis

Leonid Prigozhin; Vladimir Sokolovsky; John W. Barrett; Sergey E. Zirka

doi:10.1109/TMAG.2016.2599143

On the Energy-Based Variational Model for Vector Magnetic Hysteresis

Leonid Prigozhin, Vladimir Sokolovsky, John W. Barrett, Sergey E. Zirka

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We consider the quasi-static magnetic hysteresis model based on a dry-friction-like representation of magnetization. The model has a consistent energy interpretation, is intrinsically vectorial, and ensures a direct calculation of the stored and dissipated energies at any moment in time, and hence not only on the completion of a closed hysteresis loop. We discuss the variational formulation of this model and derive an efficient numerical scheme, avoiding the usually employed approximation, which can be inaccurate in the vectorial case. The parameters of this model for a nonoriented steel are identified using a set of first-order reversal curves. Finally, the model is incorporated as a local constitutive relation into a 2-D finite-element simulation accounting for both the magnetic hysteresis and the eddy current.

Original language	English
Article number	7539646
Journal	IEEE Transactions on Magnetics
Volume	52
Issue number	12
DOIs	https://doi.org/10.1109/TMAG.2016.2599143
State	Published - 1 Dec 2016

Keywords

Energy-based model
finite-element simulation
variational formulation
vector magnetic hysteresis

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10.1109/TMAG.2016.2599143

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abstract = "We consider the quasi-static magnetic hysteresis model based on a dry-friction-like representation of magnetization. The model has a consistent energy interpretation, is intrinsically vectorial, and ensures a direct calculation of the stored and dissipated energies at any moment in time, and hence not only on the completion of a closed hysteresis loop. We discuss the variational formulation of this model and derive an efficient numerical scheme, avoiding the usually employed approximation, which can be inaccurate in the vectorial case. The parameters of this model for a nonoriented steel are identified using a set of first-order reversal curves. Finally, the model is incorporated as a local constitutive relation into a 2-D finite-element simulation accounting for both the magnetic hysteresis and the eddy current.",

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AU - Prigozhin, Leonid

AU - Sokolovsky, Vladimir

AU - Barrett, John W.

AU - Zirka, Sergey E.

PY - 2016/12/1

Y1 - 2016/12/1

N2 - We consider the quasi-static magnetic hysteresis model based on a dry-friction-like representation of magnetization. The model has a consistent energy interpretation, is intrinsically vectorial, and ensures a direct calculation of the stored and dissipated energies at any moment in time, and hence not only on the completion of a closed hysteresis loop. We discuss the variational formulation of this model and derive an efficient numerical scheme, avoiding the usually employed approximation, which can be inaccurate in the vectorial case. The parameters of this model for a nonoriented steel are identified using a set of first-order reversal curves. Finally, the model is incorporated as a local constitutive relation into a 2-D finite-element simulation accounting for both the magnetic hysteresis and the eddy current.

AB - We consider the quasi-static magnetic hysteresis model based on a dry-friction-like representation of magnetization. The model has a consistent energy interpretation, is intrinsically vectorial, and ensures a direct calculation of the stored and dissipated energies at any moment in time, and hence not only on the completion of a closed hysteresis loop. We discuss the variational formulation of this model and derive an efficient numerical scheme, avoiding the usually employed approximation, which can be inaccurate in the vectorial case. The parameters of this model for a nonoriented steel are identified using a set of first-order reversal curves. Finally, the model is incorporated as a local constitutive relation into a 2-D finite-element simulation accounting for both the magnetic hysteresis and the eddy current.

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On the Energy-Based Variational Model for Vector Magnetic Hysteresis

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