Physical modeling and numerical computation of magnetostriction

• M. Kaltenbacher ^[1] ; M. Meiler ^[2] ; M. Ertl ^[3]
  1. [1] University of Klagenfurt

     University of Klagenfurt

     Klagenfurt, Austria

     
  2. [2] SIMetris GmbH
  3. [3] Siemens AG

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• Localización: Compel: International journal for computation and mathematics in electrical and electronic engineering, ISSN 0332-1649, Vol. 28, Nº 4 (Special Issue: Selected papers from 13th IGTE Symposium), 2009, págs. 819-832
• Idioma: inglés
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• Resumen

  • Purpose – Magnetostrictive alloys are widely used in actuator and sensor applications. The purpose of this paper is to developed a realistic physical model and a numerical computational scheme for their precise computation.

    Design/methodology/approach – The main step in the physical modeling is the decomposition of the mechanical strain and the magnetic induction into a reversible and an irreversible part. For the efficient solution of the arising coupled nonlinear partial differential equations the authors apply the finite element method.

    Findings – It can be demonstrated, that the hysteresis operators can be fitted by appropriate measurements. Therewith, the developed physical model and numerical simulation scheme is applicable for the design of magnetostrictive actuators and sensors.

    Originality/value – The decomposition of the mechanical strain and the magnetic induction into a reversible and an irreversible part. The reversible part is described by the linear magnetostrictive constitutive equations, where the entries of the coupling tensor depend on the magnetization. The irreversible part of the magnetic induction is modeled by a Preisach hysteresis operator, and the irreversible part of the mechanical strain by a polynomial function depending on the magnetization.