F. Martin;J. Taurines;O. Osemwinyen;P. Rasilo;A. Belahcen;L. Daniel
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引用次数: 0
摘要
在本文中,一个多尺度模型结合了铁磁材料的基于能量的磁滞模型。通过让磁畴随外加磁场旋转,考虑了相干旋转现象。因此,在增加旋转磁通密度的情况下,磁滞损耗的下降可以被正确地建模,而不会产生任何额外的假象。模型参数是通过微观结构 X 射线分析和标准单向磁性表征确定的。材料行为在各种磁机械负载下得到验证。最后,在变压器的有限元分析中部署了多尺度磁滞模型。该模型能正确预测准静态条件下测量到的磁通密度波形。
Magnetomechanical Multiscale Hysteresis Model of Electrical Steel Sheets in the Finite Element Simulation of a Transformer
In this article, a multiscale model incorporates an energy-based hysteresis model for ferromagnetic material. The coherent rotational phenomena are considered by letting the magnetic domains rotate with the applied field. Hence, the drop of the hysteresis losses under increasing rotational flux density can be modeled properly without any additional artifacts. The model parameters are identified from a microstructure X-ray analysis and a standard unidirectional magnetic characterization. The material behavior is validated under various magnetomechanical loadings. Finally, the multiscale hysteresis model is deployed within a finite element analysis of a transformer. The model can properly predict the measured flux-density waveform under quasistatic condition.
期刊介绍:
Science and technology related to the basic physics and engineering of magnetism, magnetic materials, applied magnetics, magnetic devices, and magnetic data storage. The IEEE Transactions on Magnetics publishes scholarly articles of archival value as well as tutorial expositions and critical reviews of classical subjects and topics of current interest.
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