Regenerative braking for an electric vehicle with a high-speed drive at the front axle
Paper in proceeding, 2021

The main contribution of this paper lies in the development of a novel front-to-rear axle brake force distribution strategy for the regenerative braking control of a vehicle with a high-speed electric drive unit at the front axle. The strategy adapts the brake proportioning to provide extended room for energy recuperation of the electric motor when the vehicle drivability and safety requirements permit. In detail, the strategy is adaptive to cornering intensity enabling the range to be further extended in real-world applications. The regenerative braking control features a brake blending control algorithm and a powertrain controller, which are decisive for enhancing the braking performance. Lastly, the regenerative braking control is implemented in the highfidelity simulation environment Simcenter Amesim, where system efficiency and regenerative brake performance are analysed. Results confirm that the designed regenerative braking greatly improves the effectiveness of energy recuperation for a front-wheel driven electric vehicle with a high-speed drive at the front axle. In conclusion, it is shown that it is feasible to use the high-speed drive with the proposed control design for regenerative braking.

brake force distribution

electric vehicle

cornering

regenerative braking

Energy efficiency

Author

Konstantinos-Ektor Karyotakis

Chalmers, Mechanics and Maritime Sciences (M2), Vehicle Engineering and Autonomous Systems

Rémi Mongellaz

Siemens Digital Industries Software

Mathias R Lidberg

Chalmers, Mechanics and Maritime Sciences (M2), Vehicle Engineering and Autonomous Systems

Proceedings of the Resource Efficient Vehicles Conference - 2021 (rev2021)

123-130
978-91-8040-047-3 (ISBN)

Resource Efficient Vehicles Conference - 2021 (rev2021)
KTH Royal Institute of Technology, Sweden,

Modular Electric Drivetrains (ModulED)

European Commission (EC) (769953), 2017-10-01 -- 2020-09-30.

Subject Categories

Vehicle Engineering

More information

Latest update

1/11/2022