Showing total 2 results

1. Magnetic Multiscale Model for Local Eddy Current Flow in Complex Materials With Insulated Conductive Particles.

Author

Fujisaki, Keisuke and Yao, Atsushi

Subjects

*MULTISCALE modeling, *MATHEMATICAL models, *MULTIVARIATE analysis, *EDDY currents (Electric), *ELECTRIC currents, *ELECTROMAGNETISM

Abstract

This paper proposes an equivalent magnetic hysteresis (B–H) curve for magnetic multiscale problems of complex materials composed of electrical conductors separated by insulating material. The conventional method, which assigns equivalent material constants to each material, cannot properly express the local eddy current loss and the extra magnetic field derived from the local eddy current. To solve this problem, we derive the magnetic hysteresis curve from the volume-averaged magnetic flux density and the surface magnetic field in the micro-model, and apply this curve to the macro-model. The mesh number of the novel macro-model is reduced to around one-tenth that of the micro-model. Magnetic hysteresis is treated by a free energy magnetic hysteresis model, and the macro-model ignores electrical conductivity. The magnetic hysteresis curve and the numerically calculated losses are consistent in the micro- and macro-models. The proposed method well expresses the local eddy current phenomena. [ABSTRACT FROM AUTHOR]

Published

2017

2. A Method for Calculating Eddy Current Loss Distribution Based on Reluctance Network Analysis.

Author

Yoshida, Yukihiro, Nakamura, Kenji, and Ichinokura, Osamu

Subjects

*EDDY currents (Electric), *ELECTRIC loss in electric power systems, *ELECTRIC networks, *MAGNETIC fields, *ELECTRIC inductance, *FINITE element method, *HYSTERESIS, *INTEGRATED circuits, *MATHEMATICAL models

Abstract

This paper presents a method for calculating eddy current loss based on reluctance network analysis (RNA) considering the magnetic reaction field caused by the eddy current. First, an electric network model for calculating eddy current is indicated. Next, RNA model considering the magnetic reaction field by using magnetic inductance is presented. The validity of the proposed model is proved by comparing with the finite-element analysis and experiment. [ABSTRACT FROM AUTHOR]

Published

2011