The global decarbonization targets require increasingly higher levels of efficiency from the designers of electrical machines. In this context, the opportunity to employ magnetic or semi-magnetic wedges in surface-mounted permanent magnet machines with fractional-slot concentrated winding has been evaluated in this paper, with the aim to reduce the power losses, especially in the magnets. Since an analytical calculation is not sufficient for this evaluation, finite element methods with two different software have been employed, by using a model experimentally validated on a real motor. The effects of wedges with different values of permeability and different magnetization characteristics have been evaluated on flux density, back electromotive force, and inductances, in order to choose the more suitable wedge for the considered motor. Furthermore, a new wedge consisting of different portions of materials with different magnetic permeability values is proposed. The effects of both conventional and unconventional magnetic wedges were assessed to optimize the motor performance in all working conditions.
[1]
Christopher Donaghy-Spargo,et al.
Use of fractional‐conductor windings and semi‐magnetic slot wedges in synchronous machines
,
2019,
The Journal of Engineering.
[2]
A. Abdel-Khalik,et al.
Nine‐phase six‐terminal pole‐amplitude modulated induction motor for electric vehicle applications
,
2019,
IET Electric Power Applications.
[3]
Hiroyuki Mikami,et al.
Dynamic harmonic field analysis of a cage type induction motor when magnetic slot wedges are applied
,
1997
.
[4]
B. J. Chalmers,et al.
Performance of some magnetic slot wedges in an open-slot induction motor
,
1967
.
[5]
Sang Bin Lee,et al.
Detection of Stator-Slot Magnetic Wedge Failures for Induction Motors Without Disassembly
,
2014
.