Power density improvement of axial flux permanent magnet synchronous motor by using different magnetic materials

Purpose The purpose of this paper is to exploit the optimal performances of each magnetic material in terms of low iron losses and high saturation flux density to improve the efficiency and the power density of the selected motor. Design/methodology/approach This paper presents a study to improve th...

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Bibliographic Details
Published in:Compel 2023-06, Vol.42 (4), p.929-946
Main Authors: Hebri, Mohamed Amine, Rebhaoui, Abderrahmane, Bauw, Gregory, Lecointe, Jean-Philippe, Duchesne, Stéphane, Zito, Gianluca, Abdenour, Abdelli, Mediavilla Santos, Victor, Mallard, Vincent, Maier, Adrien
Format: Article
Language:English
Subjects:
Automobiles
Circuit design
Circuits
Cobalt
Core loss
Driving conditions
Efficiency
Electric motors
Electric vehicles
Electrical steels
Electromagnetism
Emissions
Energy consumption
Engineering Sciences
Flux density
Hybrid electric vehicles
Injection molding
Magnetic circuits
Magnetic materials
Manufacturers
Multiple objective analysis
Permanent magnets
Permeability
Powertrain
Rotors
Stators
Steel
Synchronous motors
Urban planning
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Summary:Purpose The purpose of this paper is to exploit the optimal performances of each magnetic material in terms of low iron losses and high saturation flux density to improve the efficiency and the power density of the selected motor. Design/methodology/approach This paper presents a study to improve the power density and efficiency of e-motors for electric traction applications with high operating speed. The studied machine is a yokeless-stator axial flux permanent magnet synchronous motor with a dual rotor. The methodology consists in using different magnetic materials for an optimal design of the stator and rotor magnetic circuits to improve the motor performance. The candidate magnetic materials, adapted to the constraints of e-mobility, are made of thin laminations of Si-Fe nonoriented grain electrical steel, Si-Fe grain-oriented electrical steel (GOES) and iron-cobalt Permendur electrical steel (Co-Fe). Findings The mixed GOES-Co-Fe structure allows to reach 10 kW/kg in rated power density and a high efficiency in city driving conditions. This structure allows to make the powertrain less energy consuming in the battery electric vehicles and to reduce CO2 emissions in hybrid electric vehicles. Originality/value The originality of this study lies in the improvement of both power density and efficiency of the electric motor in automotive application by using different magnetic materials through a multiobjective optimization.
ISSN:0332-1649
2054-5606
0332-1649
DOI:10.1108/COMPEL-09-2022-0318