Overview
ABSTRACT
In order to understand the principle of electromagnetic circuits, two models are available to electricians: Maxwell's model and Kirchhoff's. The analysis of circuits is based on these basis in order to predict the evolutions of systems. This article presents various practical cases that are characteristic of the problems that can be encountered. The first one, for instance, introduces the notion of air gaps and circuit cut-offs. Another, in the form a simplified model of an electromagnetic circuit, describes the losses that appear in ferromagnetic structures. Other cases are also presented, such as moving coil actuators, toothed structures or step by step hybrid motors.
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Marcel JUFER: Doctor of Engineering - Honorary Professor, Swiss Federal Institute of Technology Lausanne - Dr HC Cluj (Romania), Mons (Belgium) and Grenoble (France)
INTRODUCTION
The analysis of Maxwell and Kirchhoff models was undertaken in the
The first example is typical of circuits such as transformers and electromagnets. It illustrates the decomposition into partial permeances.
In contrast to an analytical approach, the second example shows how to design an electromagnetic structure of a given shape to generate a force of fixed intensity.
The losses occurring in ferromagnetic structures are described using a simplified electromagnetic circuit model for eddy currents. It is thus possible to describe these losses and highlight the parameters on which they depend.
Voice coil actuators have the great advantage of generating a force proportional to the current. They have numerous applications in loudspeakers, robots, positioning machines and so on. Under certain conditions, however, they may exhibit a variable reluctance parasitic force, which will be highlighted, along with ways of eliminating it.
Many actuators or motors are made up of facing toothed structures. If they can be modeled efficiently by finite element methods, it may be worthwhile to use equivalent circuit modeling. Variable permeances can be determined by approximating field lines by straight lines and arcs.
The complex magnetic structure of the hybrid stepper motor is difficult to control, even using finite elements. A magnetic equivalent circuit model is proposed, using in particular the permeance model already studied.
The basic principles of electromagnetism in the stationary (low-frequency) domain, and the resulting methodology for magnetic circuits, are described in
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Magnetic circuits
Bibliography
Tools and software
Circuits http://www.5spice.com/download.htmhttp://www.next.gr/software/circuit-analysis
Events
IMACS conferences http://www.mssanz.org.au/modsim09http://www.imacs.polytechnique.frhttp://www.lmpa.univ-littoral.fr/IMACS09
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