Model and simulations of hysteresis in magnetic cores

Author

Boley, C.D. ; Hodgdon, M.L.

Author_Institution

Lawrence Livermore Nat. Lab., CA, USA

Volume

25

Issue

5

fYear

1989

fDate

9/1/1989 12:00:00 AM

Firstpage

3922

Lastpage

3924

Abstract

The authors present simulations of the hysteresis experienced by a ferromagnetic core as it dissipates energy in an RLC circuit. The calculations utilize the Hodgdon theory of ferromagnetic hysteresis, along with a model of the core geometry. The theory allows for both rate-independent and rate-dependent effects, with the latter often having a marked influence on the hysteresis. The hysteresis theory involves a number of parameters, some of which are obtained from major loop data and the rest of which are deduced from circuit data. Results obtained for three materials-CN20, C2025, and Vitrovac-show that the predicted voltage waveform can be brought into agreement with experiment

Keywords

magnetic cores; magnetic hysteresis; modelling; simulation; C2025; CN20; Hodgdon theory; RLC circuit; Vitrovac; core geometry model; energy dissipation; ferromagnetic core; hysteresis; magnetic cores; major loop data; predicted voltage waveform; rate-dependent effects; rate-independent effects; simulations; Circuit testing; Laboratories; Magnetic cores; Magnetic hysteresis; Magnetic materials; Permeability; Switched capacitor circuits; Switches; Switching circuits; Voltage;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/20.42478

Filename

42478