Design and Evaluation of a HRE-Free PMSM Rotor for Heavy-Duty Applications A Combined Literature and Simulation Approach Considering HRE-Free Rotor Design
Hämtar...
Publicerad
Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
Tidskriftstitel
ISSN
Volymtitel
Utgivare
Sammanfattning
Permanent magnet synchronous machines (PMSMs) are widely used in heavy-duty electric
powertrains due to their high efficiency and torque density. However, conventional NdFeB
rotor magnets often contain heavy rare earth elements (HREs), such as dysprosium and
terbium, to improve coercivity and in turn thermal stability. This thesis evaluates the
feasibility of removing HREs from NdFeB magnets in a double-layer V-shaped PMSM
rotor. The work combines a sustainability analysis of rare earth elements (REEs) with
electromagnetic simulations in Ansys Motor-CAD, including magnet screening, demagnetization
assessment, custom magnet evaluation, rotor geometry studies, optimization, and
benchmarking against the original HRE-based reference design.
The sustainability analysis shows that reducing HRE content can lower material cost,
reduce environmental burden, and decrease dependence on critical REEs. However, HRE
reduction does not remove all sustainability challenges, since REE supply remains affected
by geopolitical concentration, processing capacity, environmental risks, and low recycling
rates. The simulation results show that replacing the original HRE-based magnet with
available HRE-free magnets in the unchanged rotor geometry is not sufficient to meet
both torque and demagnetization requirements. At 140◦C under short circuit conditions,
the original HRE-free 45SH and 42SH rotor cases reached only approximately 335 Nm and
320 Nm after demagnetization, compared with approximately 505 Nm for the HRE-based
reference design. High intrinsic coercivity, and strong coercivity retention at elevated
temperatures are critical for limiting irreversible demagnetization under short circuit
condition. Rotor geometry optimization significantly improves the HRE-free designs,
especially through increased magnet thickness up to 6.00 mm, but introduces trade-offs
between demagnetization resistance, torque performance, and magnet weight. Overall,
the results show that an HRE-free PMSM rotor application is possible only if magnet
material properties and rotor geometry are designed together.
Beskrivning
Ämne/nyckelord
PMSM, HRE-free magnets, demagnetization, coercivity, remanence, sustainability, rare earth elements (REEs)
