EAL, Institut für elektrische Antriebe und Leistungselektronik

Institut für elektrische Antriebe und Leistungselektronik

JKU, Johannes Kepler Universität Linz

Sprache: DE

Publikations Einzelansicht

Optimization and Realization of a Multi-Pole Permanent Magnetic Bearing with Rotating Magnetization


Autor(en): Edmund Marth, Gerald Jungmayr, Martin Panholzer und Wolfgang Amrhein
Journal: Journal of Systems and Control Engineering: April 2016; 230 (4) Verlag Sage Journals, Print ISSN: 0959-6518 Online ISSN: 2041-3041 SCI-expanded Zeitschrift
Jahr: 2016
Band: 230
Ausgabe: 4
Seite(n): 320-329
DOI: 10.1177/0959651815594081
Datei / URL: http://pii.sagepub.com/content/230/4.toc
Zusammenfassung: The focus of this paper is on optimizing the stiffness of a permanent magnetic single-ring bearing solely by changing the magnetization pattern. More precisely, using rotating magnetization with two magnetic poles rather than homogeneous magnetization results in a 3.7-fold improvement in stiffness. Usually, rotating magnetization is realized by Halbach stacking, that is, stacking several homogeneously magnetized rings with different directions of magnetization. The approach followed in this work realizes a continuously rotating magnetization pattern using only one ring. Optimization of the magnetization process, as presented in this paper, is crucial to achieving the maximum possible stiffness for the specified bearing dimensions. Furthermore, an analytical stiffness calculation method for bearings with arbitrary magnetization pattern is introduced, and the results are compared with finite-element calculations and measurements.

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