DocumentCode
1057487
Title
Comprehensive Efficiency Modeling of Electric Traction Motor Drives for Hybrid Electric Vehicle Propulsion Applications
Author
Williamson, Sheldon S. ; Emadi, Ali ; Rajashekara, Kaushik
Author_Institution
Concordia Univ., Montreal
Volume
56
Issue
4
fYear
2007
fDate
7/1/2007 12:00:00 AM
Firstpage
1561
Lastpage
1572
Abstract
Extensive research done in the recent past has proven that power electronic converters and electric propulsion motors are extremely critical components for modern hybrid electric vehicle (HEV) propulsion applications. Therefore, it is essential that both the traction motor and the associated drive operate at their optimal efficiencies throughout the driving schedule. In typical HEV propulsion applications, the traction motor and the drive are used over the entire torque/speed operational range. In view of this fact, this paper aims at modeling the inverter and motor losses/efficiencies over typical city and highway driving schedules. The noteworthy losses within a typical three-phase dc/ac traction inverter, such as the switching and conduction losses for both the insulated-gate bipolar transistors and the antiparallel diodes, are modeled and simulated over the city and highway driving patterns. An induction motor (IM) is used for a medium-sized sport utility vehicle, which was modeled in the advanced vehicle simulator (ADVISOR) software. The significant IM losses that were considered in the study include the stator copper losses, rotor copper losses, and core losses. Thus, the average efficiencies of both the inverter drive and the induction traction motor are evaluated and summarized under city as well as highway driving conditions. Finally, based on the individual-model-based efficiency analysis, the overall traction motor drive system efficiency is estimated.
Keywords
electrical engineering computing; hybrid electric vehicles; induction motor drives; invertors; traction motor drives; advanced vehicle simulator; antiparallel diodes; core loss; efficiency modeling; electric propulsion motors; electric traction motor drives; hybrid electric vehicle propulsion; induction motor; insulated-gate bipolar transistors; inverter drive; motor efficiency; motor loss; power electronic converters; rotor copper loss; stator copper loss; three-phase dc-ac traction inverter; Cities and towns; Copper; Hybrid electric vehicles; Insulation; Inverters; Power electronics; Propulsion; Road transportation; Torque; Traction motors; Electric propulsion; induction machines; inverters; losses; modeling; simulation; traction motor drives;
fLanguage
English
Journal_Title
Vehicular Technology, IEEE Transactions on
Publisher
ieee
ISSN
0018-9545
Type
jour
DOI
10.1109/TVT.2007.896967
Filename
4273755
Link To Document