An accurate magnetic equivalent circuit model for modeling and analysis of variable reluctance energy harvesters

Document Type : Research Article

Author

Department of Electrical Engineering, Lorestan University, Khorramabad, Lorestan, Iran.

Abstract

Variable Reluctance Energy Harvester (VREH) is a good candidate for transducers to transform environmental energy into electricity. VREHs act based on electromagnetic induction due to the variation of air-gap reluctance with the rotation of the wheel. This paper presents an accurate analytical model based on Magnetic Equivalent Circuit (MEC) model and Conformal Mappings (CMs) for
electromagnetic modeling of the VREHs, which have a large air-gap. The geometry of the analyzed
VREH on both sides of air-gap including the iron parts, slots, and Permanent Magnets (PMs) is divided
into many elements in cylindrical coordinates, and each element is then replaced with an equivalent
permeance model. The air-gap, including region is modeled with permeances calculated by the CM
method, which can accurately consider the real paths of flux tubes in large air-gap. The obtained airgaps
permeances are then used in the MEC model for electromagnetic modeling and analysis of the
studied VREH, while considering the effects of slots and magnetic saturation, accurately. Finally, the
analytical results are verified by comparing with the corresponding results obtained through Finite
Element Method (FEM).

Keywords

Main Subjects

References

References
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Scientia Iranica
Volume 32, Issue 10
Transactions on Computer Science & Engineering and Electrical Engineering
May and June 2026 Article ID:7133

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History

  • Receive Date: 05 September 2022
  • Revise Date: 01 January 2023
  • Accept Date: 22 February 2023

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