Title :
Design and Performance of a Water-cooled Permanent Magnet Retarder for Heavy Vehicles
Author :
Ye, Lezhi ; Li, Desheng ; Ma, Yuanjing ; Jiao, Bingfeng
Author_Institution :
Coll. of Mech. Eng. & Appl. Electron. Technol., Beijing Univ. of Technol., Beijing, China
Abstract :
This paper proposes a novel permanent magnet retarder (PMR) structure that uses water cooling to improve the braking performance of conventional PMR for heavy vehicles. A finite element model for a water-cooled PMR was developed by considering the temperature dependence of magnetic characteristics and heat conductivity. The eddy current and temperature distribution were analyzed using the magneto-thermal coupled method. Retarder performance was tested at a test bench. The test results show that the calculated temperature and braking torque agreed fairly well with the measured results. PMRs can maintain a low working temperature by using water cooling. Compared with air-cooled retarder, this retarder´s braking torque does not decrease much under continuous working conditions.
Keywords :
braking; cooling; eddy currents; electric vehicles; finite element analysis; heat conduction; permanent magnet motors; temperature distribution; PMR structure; eddy current; finite element model; heat conductivity; heavy vehicles; magnetic characteristics; magneto-thermal coupled method; retarder braking torque; temperature dependence; temperature distribution; water cooling; water-cooled permanent magnet motor retarder; Cooling; Eddy currents; Magnetic analysis; Perpendicular magnetic recording; Stators; Temperature measurement; Torque; Eddy currents; magneto-thermal coupled analysis; permanent magnet (PM); retarder; water cooling;
Journal_Title :
Energy Conversion, IEEE Transactions on
DOI :
10.1109/TEC.2011.2157347
