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Electric vehicles with the wheels individually driven by e-motors have promising potential for improving performance through finer control over the power distribution among the wheels. Due to the absence of a mechanical driveline to connect the wheels to the transmission and engine, the virtual driveline system (VDS) is proposed as a conceptual framework to connect virtu-ally the individual electric motors and, thus, to optimize and analyze the dynam-ics and performance of vehicles. Conceptually, the VDS is based on vehicle-gen-eralized parameters (VGP), which are used in the VDS principle to establish re-lationships between VGPs and, thus, to manage the wheel power split and set up interactive/coordinated controls of the e-motors to optimize and improve energy efficiency, terrain mobility performance, maneuver, etc. Keywords: Vehicle Dynamics Theory, Modeling
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4x4 Hybrid Electric Vehicle vs. Fully Electric Vehicle Mobility in Drastically Changing Terrain Conditions
Active driveline technologies allow vehicles to dynamically control power distribution among driving wheels to improve vehicle operational parameters that impact terrain mobility. Two 4x4 electrified drivelines are compared which provide a variable power split: a hybrid electric vehicle with a controllable power transmitting unit and a fully electric vehicle (FEV) with individual electric wheel drives. The individual e-drives have the potential to improve mobility when the left and right wheel terrain conditions are drastically different.
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- Award ID(s):
- 1849264
- PAR ID:
- 10214004
- Date Published:
- Journal Name:
- Proceedings of the 3rd International Conference of IFToMM Italy
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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