Autors: Stoyanov, T. M., Rizov, P. M.
Title: Investigation of the cooling of a permanent magnet synchronous motor with different types of coolants
Keywords: Ansys Maxwell 2015, different types of coolants, electromagnetic loads, inlet temperatures, permanent magnet synchronous motor, spatial distribution of the temperatureAbstract: One of the main factors that influence the performance of permanent magnet synchronous motors - used in electric and hybrid vehicles is the type, structure and operation of the motor's cooling system. On the one hand, the motor is subjected to significant electromagnetic loads, and on the other hand, the cooling of the permanent magnets and the stator winding is of particular importance for the operation of the motor. The article presents data from investigation of the cooling of a permanent magnet synchronous motor with different types of coolants- antifreeze and oil by using the software product Ansys Maxwell 2015. The properties of materials and coolants that are set in the model are presented. At different inlet temperatures (up to twice the motor's rated power) of the coolant the spatial distribution of the temperature, the minimum and maximum temperature in different parts of the motor are determined –stator, rotor, coil sides, end connection, magnet, motor frame. References - I. Bachev, V. Lazarov, L. Stoyanov, Z. Zarkov, Feasibility study of a hybrid excited claw-pole alternator, 18th Conference on electrical machines, drives and power systems (ELMA), 2023.
- G. Dilevrano, P. Ragazzo, S. Ferrari, G. Pellegrino, T. Burress, Magnetic, thermal and structural scaling of synchronous machines, IEEE Energy Conversion Congress and Exposition (ECCE), 2022.
- C. Kilic, E. Mese, Comparison of high switching frequency operated high speed motor drive systems, 3rd Global power, energy and communication conference (GPECOM), 2021.
- M. Rilla, Design of salient pole pm synchronous machines for a vehicle traction application – analysis and implementation, 2012. https://lutpub.lut.fi/bitstream/handle/10024/86335/isbn%209789522653376.pdf?sequence=1&isAllowed=y
- W. Soong, Thermal analysis of electrical machines: limits and heat transfer principle, 2008. http://www.eleceng.adelaide. edu.au/ research/power/pebn/pebn003%20thermal%20analysis%20of%20elec trical%20machines%20limits%20and%20heat%20transfer%20princip les.pdf
- Q. Wang, Y. Wu, S. Niu, X. Zhao, Advances in thermal management technologies of electrical machines, 2022. https://www.researchgate.net/publication/360296091_Advances_in_Thermal_Management_Tec hnologies_of_Electrical_Machines
- https://electricalbaba.com/electrical-insulation-classes/
- https://www.electronics-cooling.com/2009/02/antifreeze-coolants/
- https://www.engineeringtoolbox.com/ethylene-glycol-d_146.html
- https://www.infineuminsight.com/media/2967/11-e-mobility-and-electrification-na.pdf
- https://www.leroy-somer.com/documentation_pdf/5202_en.pdf
- https://www.swiftsupplies.com.au/news-tips-and-guides/electricalinsulation-temperature-classes-explained/
- https://thermtest.com/application/thermal-properties-of-automotive-related-fluids
- https://wiki.anton-paar.com/en/automatic-transmission-fluid-atf/
Issue
| 2024 16th Electrical Engineering Faculty Conference, BulEF 2024, 2024, , https://doi.org/10.1109/BULEF63204.2024.10794928 |
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