Performance Optimization Analysis of Hybrid Excitation Generator With the Electromagnetic Rotor and Embedded Permanent Magnet Rotor for Vehicle

To solve the problems of the non-adjustable magnetic field of the permanent magnet (PM) generator, large excitation loss and high failure rate of electric excitation generator, this paper proposes a parallel electromagnetic and PM hybrid excitation generator (HEG). The designed generator adopts a hi...

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Bibliographic Details
Published inIEEE access Vol. 9; pp. 163640 - 163653
Main Authors Geng, Huihui, Zhang, Xueyi, Tong, Lanian, Ma, Qingzhi, Xu, Mingjun, Zhang, Yufeng, Wang, Lei
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Circuit design
Combined-pole rotor
Electric potential
Electric power distribution
equivalent magnetic circuit method
Excitation
Failure rates
Finite element method
Generators
hybrid excitation generator
Magnetic circuits
Magnetic fields
Magnetic flux
Magnetism
Optimization
Permanent magnets
Rotors
Stator cores
Stator windings
Steel
vehicles
Voltage
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Summary:To solve the problems of the non-adjustable magnetic field of the permanent magnet (PM) generator, large excitation loss and high failure rate of electric excitation generator, this paper proposes a parallel electromagnetic and PM hybrid excitation generator (HEG). The designed generator adopts a high power density PM rotor composed of built-in tangential PM steel and V-shaped PM steel and a salient-pole electromagnetic rotor (EMR) with short axial length, less electromagnetic loss, simple and reliable structure. By adjusting the axial length of two rotors and the size of magnetomotive force sources, the generator can adjust the rotor power distribution to meet various power requirements. Meanwhile, the HEG can adjust the electromagnetic magnetic field (EMMF) by adjusting the size and direction of the excitation current, and then can adjust the size of the synthetic magnetic field to achieve the purpose of stabilizing output voltage. In this paper, the magnetic circuit model of the HEG is established by using the equivalent magnetic circuit (EMC) method, and the rationality of the designed magnetic circuit is verified and analyzed by the finite element method. The prototype is trial-manufactured and tested, and the results show that the designed HEG has a wide magnetic regulation range, stable output voltage, and good output performance.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3133960