The Transactions of the Korean Institute of Power Electronics (전력전자학회논문지)

The Korean Institute of Power Electronics (전력전자학회)
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A Study on Flux Barrier of Permanent Magnet Assisted Reluctance Synchronous Motor Design using FEM

FEM을 이용한 영구자석형 릴럭턴스 동기전동기의 자속 장벽 설계에 대한 연구

  • Published : 2008.08.20
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Abstract

This paper examines the design and the performance of a PMA-RSM(permanent-magnet assisted reluctance synchronous motor) for washing machine. A FEM(finite element method) is used to analyze performance and maximum torque characteristic of the proposed PMA-RSM. The designed motor is a combination of salient poles, which is making reluctance torque, and permanent magnet which are located on the air-gap of rotor to get a enough torque during low speed resign. Typical flux barrier type reluctance synchronous motor and the effects of adding magnet into the flux barrier of the rotor of a PMA-RSM are compared and examined. Also the maximum torque point of the reluctance torque by reluctance and reaction torque by magnetic alignment torque, which is in barrier, of the proposed PMS-RSM are derived through simulation. Using this results, the characteristics analysis of a performance, an average torque and a torque ripple of flux barrier RSM and the proposed PMA-RSM are performed through FEM under the saturation effect respectively.

본 논문에서는 세탁기용으로 사용될 영구자석형 릴럭턴스 동기전동기(permanent-magnet assisted reluctance synchronous motor : PMA-RSM)의 설계와 특성에 대해서 살펴본다. 제안된 PMA-RSM의 특성과 최대 토크 특성을 알아보기 위해서 유한 요소법(finite element method)을 이용 하였다. 저속 구간에서의 충분한 토크를 발생시키기 위해서 회전자의 구조는 릴럭턴스 토크를 만들어내는 돌극 구조와 회전자 내부의 공극에 영구자석을 삽입하는 구조로 구성되어 있다. 전형적인 자속 장벽형(Flux barrier type) 릴럭턴스 동기전동기(RSM : Reluctance Synchronous Motor)와 자속 장벽(Flux barrier)에 자석을 삽입한 경우에 발생되는 현상들에 대해서 비교 분석하고, 또한 제안된 PMA-RSM의 릴럭턴스 토크(reluctance torque)와 자석에 의한 자석 토크(magnetic alignment torque)가 서로 최대가 되는 시점을 시뮬레이션을 통하여 구하며, 그 결과를 이용하여 전동기의 특성, 평균토크 그리고 토크 리플에 대해서 유한 요소법을 통하여 살펴보았다.

Keywords

References

  1. W. L. Soong, and T. J. E. Miller, "Design of a New Axially Laminated Interior Permanent Magnet Motor", Proceeding of annual meeting of IEEE Industrial Applications Society, pp. 27-36, 1993
  2. I. Boldea, Reluctance Synchronous Machines and Drives, Clarendon PRESS, OXFORD, 1996
  3. Maxwell, Electrical engineering Simulation Software, Copyright 1984-2003, Ansoft Corporation
  4. A. Vagati, A. Canova, M. Chiampi, M. Pastorelli, M. Repetto, "Design refinement of synchronous reluctance motors through finite-element analysis", IEEE Transactions on IA, Vol. 36, No. 4, pp. 1094-1102, 2000. July-Aug
  5. A. Vegati, A. Canova, and M. Pastorelli, "Design and control of high performance synchronous reluctance motor with multiple flux-barrier rotor", IPEC 2000, Tokyo, Japan
  6. P. Guglielmi, M. Pastorelli, and A. Vagati, "Impact of cross-saturation in sensorless control of transverse-laminated synchronous reluctance motors", IEEE Transactions on IE, Vol. 53, No. 2, pp. 429-439, 2006, April
  7. A. Boglietti, A. Cavagnino, M. Pastorelli, D. Staton, and A. Vagati, "Thermal analysis of induction and synchronous reluctance motors", IEEE Transactions on IA, Vol. 42, No. 3, pp. 675-680, 2006, May-June