Modelling and heuristic control of a parallel hybrid electric vehicle

Author:

Enang Wisdom1,Bannister Chris1,Brace Chris1,Vagg Chris1

Affiliation:

1. University of Bath, Bath, UK

Abstract

Hybrid electric vehicles offer the potential for fuel consumption improvements when compared with conventional vehicle powertrains. The fuel consumption benefits which can be realised when utilising the hybrid electric vehicle architecture are dependent on how much braking energy is regenerated, and how well the regenerated energy is utilised. A number of power management strategies have been proposed in literature. Owing to the prospect of real-time implementation, many of these proposals have centred on the use of heuristics. Despite the research advances made, the key challenge with heuristic strategies remains achieving reasonable fuel savings without over-depleting the battery’s state of charge at the end of the trip. In view of this challenge, this paper offers two main contributions to existing energy management literature. The first is a novel, simple but effective heuristic control strategy which employs a tuneable parameter (the percentage of the maximum motor tractive power) to decide the control sequence, such that impressive fuel savings are achieved without over-depleting the final state of charge of the battery (the battery energy). The second is the quantitative exploration of braking patterns and its impact on kinetic energy regeneration. The potential of the proposed heuristic control strategy was explored over a range of driving cycles which reflect different driving scenarios. The results from this analysis show that fuel savings of as much as 19.07% can be achieved over the Japan 10–15 driving cycle. In comparison with a suboptimal controller whose control signals were derived from dynamic programming optimal control, our proposed strategy was found to be outperforming, in that it achieved impressive real-time fuel savings without much penalty to the final state of charge of the battery. Gentle braking patterns were also found to significantly improve brake energy regeneration by the electric motor.

Publisher

SAGE Publications

Subject

Mechanical Engineering,Aerospace Engineering

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1. Energy Management Systems’ Modeling and Optimization in Hybrid Electric Vehicles;Energies;2024-04-02

2. A Logic Threshold Control Strategy to Improve the Regenerative Braking Energy Recovery of Electric Vehicles;Sustainability;2023-12-14

3. Model Predictive Eco-Driving Control for Heavy-Duty Trucks Using Branch and Bound Optimization;IEEE Transactions on Intelligent Transportation Systems;2023-12

4. E-Vehicle Performance Analysis using MATLAB ADVISOR Tool;2023 2nd International Conference on Advancements in Electrical, Electronics, Communication, Computing and Automation (ICAECA);2023-06-16

5. Performance Study of a Developed Rule-Based Control Strategy with Use of an ECMS Optimization Control Algorithm on a Plug-In Hybrid Electric Vehicle;Strojnícky časopis - Journal of Mechanical Engineering;2022-11-01

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