Title :
Numerical Analysis and Experimentation of a Novel Self-Excited and Liquid-Cooled Eddy Current Retarder
Author :
Kai Zhang ; Desheng Li ; Xiao Du ; Ran Zheng
Author_Institution :
Coll. of Mech. Eng. & Appl. Electron. Technol., Beijing Univ. of Technol., Beijing, China
Abstract :
To overcome the serious thermal recession problem that has been associated with the braking torque of conventional eddy current brakes, and to conserve energy, this paper has proposed a novel self-excited eddy current retarder (S-ECR). The design includes a stator with an internally cooled channel, a rotor with double salient poles, and a built-in generator. The electromagnetic field analysis and the performance analysis of the S-ECR were carried out using the finite-element method. The S-ECR performance was tested at a test bench. The test results showed that the calculated braking torque and the generator performance were in reasonable agreement with the measured results. The braking performance did not obviously diminish during the continuous braking stage. When the speed was 1500 r/min and the exciting current was 30 A, the braking torque could reach 1600 N·m.
Keywords :
brakes; eddy current braking; electric generators; electromagnetic fields; finite element analysis; rotors; torque; S-ECR; braking torque; built-in generator; double salient poles; eddy current brakes; electromagnetic field analysis; energy conservation; finite-element method; internally cooled channel; liquid-cooled eddy current retarder; numerical analysis; rotor; self-excited eddy current retarder; stator; thermal recession problem; Analytical models; Eddy currents; Generators; Magnetic hysteresis; Rotors; Stators; Torque; Eddy current retarder (ECB); electromagnetic field; liquid-cooled; numerical analysis; self-excited;
Journal_Title :
Energy Conversion, IEEE Transactions on
DOI :
10.1109/TEC.2013.2295218
