Modeling of history–dependent magnetization in the finite element method on the example of a postassembly rotor magnetizer. Bavendiek, G., Müller, F., Steentjes, S., & Hameyer, K. International Journal of Numerical Modelling: Electronic Networks, Devices and Fields, 33(5):1–10, 2019.
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Paper doi abstract bibtex 4 downloads
Paper doi abstract bibtex 4 downloads Demagnetization characteristics of permanent magnets play a central role for the design and optimization process of permanent magnet electrical machines and magnetic actuators. Currently, practical issues, such as loss of performance of electromagnetic energy conversion devices, due to demagnetization effects in permanent magnets or due to reduced servo–dynamics in magnetic actuators, cannot be addressed by using conventional material models or are investigated by using rough approximations valid in restricted operation regions, if at all. This paper strives to integrate demagnetizing characteristics dependent on previous magnetizing field strength in the finite element method. The discussed examples are a magnetizer of a single permanent magnet and a spoke–type permanent magnet rotor.
@article{Bavendiek.2019b,
abstract = {Demagnetization characteristics of permanent magnets play a central role for the design and optimization process of permanent magnet electrical machines and magnetic actuators. Currently, practical issues, such as loss of performance of electromagnetic energy conversion devices, due to demagnetization effects in permanent magnets or due to reduced servo--dynamics in magnetic actuators, cannot be addressed by using conventional material models or are investigated by using rough approximations valid in restricted operation regions, if at all. This paper strives to integrate demagnetizing characteristics dependent on previous magnetizing field strength in the finite element method. The discussed examples are a magnetizer of a single permanent magnet and a spoke--type permanent magnet rotor.},
author = {Bavendiek, Gregor and M{\"u}ller, Fabian and Steentjes, Simon and Hameyer, Kay},
year = {2019},
title = {{Modeling of history--dependent magnetization in the finite element method on the example of a postassembly rotor magnetizer}},
keywords = {demagnetization;magnetic hysteresis;magnetization processes;permanent magnets (PMs)},
pages = {1--10},
volume = {33},
number = {5},
journal = {{International Journal of Numerical Modelling: Electronic Networks, Devices and Fields}},
doi = {10.1002/jnm.2674},
url = {http://bib.iem.rwth-aachen.de/IEMpublications/2019GBModeling.pdf}
}Downloads: 4
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