Electrical-Continuously Variable Transmission System Based on Doubly Fed Flux-Bidirectional Modulation

Electrical-Continuously Variable Transmission System Based on Doubly Fed Flux-Bidirectional Modulation

A brushless power split system is presented in this paper. The proposed system offers an electric solution for continuously variable transmission (CVT) in hybrid electrical vehicles (HEVs). The key contribution is to use a doubly fed flux-bidirectional-modulation (DF-FBM) machine with two electric p...

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Bibliographic Details
Published in:IEEE transactions on industrial electronics (1982) Vol. 64; no. 4; pp. 2722 - 2731
Main Authors: Wang, Yunchong, Niu, Shuangxia, Fu, Weinong
Format: Journal Article
Language:English
Published: New York IEEE 01-04-2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Computer simulation
Continuously variable
Converters
Electric continuously variable transmission (E-CVT)
Finite element method
finite-element method (FEM)
Flux
flux bidirectional modulation
hybrid electrical vehicle (HEV)
Hybrid vehicles
Mathematical analysis
Mathematical model
Mathematical models
Modulation
Ports
Product design
Rotors
Stator windings
Torque
Transmissions (automotive)
Windings
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Description
Summary:A brushless power split system is presented in this paper. The proposed system offers an electric solution for continuously variable transmission (CVT) in hybrid electrical vehicles (HEVs). The key contribution is to use a doubly fed flux-bidirectional-modulation (DF-FBM) machine with two electric ports and two concentric mechanical ports to realize power combination and split in HEV. The torque distribution relationship between two rotors is derived from the mathematical model of the DF-FBM machine and verified by simulation using finite-element method (FEM) and experiment results. This electric CVT system not only integrates the merits of the dual rotor machine and flux modulation machine but also enjoys additional benefits such as high torque density and low-cost partial-scale converter. The operation principle, flux modulation principle, and steady performance of the machine are investigated. Control strategy with dual rotor position feedback is developed. Time stepping FEM is used to analyze the dynamic performance of the proposed system. A prototype is fabricated and the experimental results verify the validity of the mathematical model and simulation results.
ISSN:0278-0046
1557-9948
DOI:10.1109/TIE.2016.2637885