Design of a High-Specific-Power Traction Motor: Innovations and Strategies for Superior Performance

Design of a High-Specific-Power Traction Motor: Innovations and Strategies for Superior Performance

In electric vehicle (EV) traction, energy conversion by electric motors must be material and energy efficient to reduce environmental burden caused by the manufacture and operation of the systems and to help in efficient transition towards net zero future. The scarcity of key materials like rare ear...

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Main Authors: Juha J. Pyrhonen, Ilya Petrov, Daniil Zadorozhniuk, Lasse Laurila, Miika Parviainen, Giota Goswami, Charles Nutakor, Jussi Sopanen, Iikka Martikainen, Dieter Zeppei, Jonas Bickel, Jenni Pippuri-Makelainen, Janne Keranen, Kalle Kinnunen, Juho Montonen
Format: Article
Language:English
Published: IEEE 2025-01-01
Series:IEEE Access
Subjects:
Energy conversion
energy system
electric motor
traction motor
electric vehicle
non-road electric vehicle
Online Access:https://ieeexplore.ieee.org/document/11082312/
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Summary:In electric vehicle (EV) traction, energy conversion by electric motors must be material and energy efficient to reduce environmental burden caused by the manufacture and operation of the systems and to help in efficient transition towards net zero future. The scarcity of key materials like rare earths and to some extent copper must be addressed in the design. Novel traction motors need a different approach compared to traditional industrial motor designs. Here, we focus on innovative design and optimization strategies to enhance material and energy efficiency and meet the escalating demand for sustainable transportation solutions. We are developing a prototype motor that achieves a continuous specific power of 7 kW/kg, significantly exceeding current automotive standards. This will be achieved by elevated operational speed of the traction motor, integrating advanced materials, and innovative cooling techniques such as direct liquid cooling (DLC) using hollow hairpin conductors, and insulating them with polyether-ether-ketone (PEEK) extrusion and expandable mainwall insulation material. The approach reduces reliance on rare earth permanent magnet (PM) materials by 60% compared to existing motors, aligning with global sustainability objectives. Through simulation, modeling, and practical case studies, the research demonstrates the feasibility of these innovations in real-world applications, highlighting potential advancements in EV propulsion systems. The article not only represents the insights into the latest developments in the design of electric motors for EV but also delineates the journey towards the creation of such a motor with considering accompanying electromagnetic and mechanical challenges.
ISSN:2169-3536

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