Design and performance evaluation of a medium power PM-assisted reluctance synchronous traction machine using bonded PM-sheets
SAIEE Africa Research Journal
Electrical Machines and Drives Laboratory, Department of Electrical and Electronic Engineering, University of Stellenbosch, Matieland, 7602, South Africa
This paper describes the optimum design of a permanent-magnet-assisted reluctance rotor of a 110 kW reluctance synchronous traction machine. Previous studies show that the performance of the pure reluctance synchronous machine drive deteriorates fast in the flux-weakening speed region. To address this problem, thin bonded permanent-magnet sheet material is used inside the flux barriers of the reluctance rotor to improve the performance of the drive, especially in the flux-weakening speed region. A design optimization algorithm is implemented to minimize the volume and hence the cost of the permanent-magnet material, subject to voltage and torque constraints. The calculated and measured results show clearly that the performance of the reluctance synchronous traction machine with a minimum amount of permanent-magnet material in the rotor compares favorably with the performance of the conventional induction machine drive at both rated and maximum speeds. Copyright © 2004 IEEE.
Design optimization; Finite Element; Flux barrier; Flux weakening; Induction machine drive; Maximum speed; Measured results; Optimisation; Optimisations; Optimum designs; Performance evaluation; Reluctance synchronous machine; Sheet material; Torque constraints; Traction machines; Magnetic devices; Optimization; Permanent magnets; Synchronous motors; Traction (friction); Machine design