The Library
Development of an optimal, real-time implementable, energy management strategy for a parallel hybrid two-wheeler : innovation report
Tools
Kommuri, Naga Kavitha (2021) Development of an optimal, real-time implementable, energy management strategy for a parallel hybrid two-wheeler : innovation report. EngD thesis, University of Warwick.
PDF
WRAP_Theses_Kommuri_2021.pdf - Submitted Version Embargoed item. Restricted access to Repository staff only until 15 June 2024. Contact author directly, specifying your specific needs. - Requires a PDF viewer. Download (5Mb) |
Official URL: http://webcat.warwick.ac.uk/record=b3850023~S1
Abstract
Concerns over rising CO2 emissions, poor air quality and energy sustainability have led the transportation sector to investigate technologies for a reduction of emissions. EV, HEV and PHEV are all potential solutions with PHEV gathering attention in certain sec-tors. However, there are significant barriers to wider penetration of this technology, pri-marily variability in fuel economy, the effect on the reliability of other subsystems, and battery lifetime. One important method to address these concerns is through the develop-ment of an intelligent energy management strategy of a PHEV which optimises the trade-offs between fuel economy, factors affecting battery lifetime and engine stop-start reliabil-ity which up until now have not been considered.
This work investigates the effect of EMS on p., engine on/off transitions and factors influencing battery ageing. This research programme has the objective of laying down a foundation for future improvements in energy management development and its optimization and provides aid in establishing a basis for comparing energy management controllers, which are real-time capable and thus applicable to current vehicles.
Firstly, a modified rule-based strategy based on load levelling was developed which showed a considerable benefit in fuel economy over the basic rule-based strategy, which had not previously been investigated in-depth for a 2-wheeler application. Variations in the system parameters had a significant influence on the fuel economy benefit through load levelling. Secondly, a novel modified Equivalent fuel Consumption Minimization Strategy was developed considering the engine operating point deviation from the optimum line. The modified ECMS strategy referred to as ECMS_LL showed enhanced benefit in fuel economy when compared to the basic ECMS strategy. The third avenue of investigation was focused on an all-inclusive evaluation of this modified ECMS_LL with other state-of-art energy -management strategies concerning battery ageing, engine on/off switching along with fuel economy and charge sustainability. There was considerable improvement in fuel economy of up to 12.98 % and a reduction in the engine on/off transitions of up to 55% while using modified ECMS compared to rule-based strategies. However, this re-sulted in negative potential effects on critical battery parameters influencing battery ageing. There was a detrimental effect on absolute battery temperature and absolute battery throughput, which increased by 11.4 ºC and 8.32 Ah respectively. The results were ana-lysed and found consistent for two different drive cycles and three different powertrain component configurations. Lastly, a unique cost-effective solution of equivalence factor adaptation using learning vector quantitative neural network-based drive cycle recognition was developed for the real-time implementation of ECMS_LL. A maximum of 10.70% fuel benefit was seen by using the LVQNN based estimation of equivalence factors in AECMS_LL over an ECMS_LL using equivalence factor optimized for a single drive cy-cle.
In conclusion, the work presented provides a detailed insight into the systematic development of a real-time implementable optimal-control based energy management strategy for the full parallel hybrid two-wheeler application considered. This research also defines a robust evaluation process for energy management strategies, including the effects of fuel economy optimisation on battery life and engine switching while comparing energy management strategies.
Item Type: | Thesis (EngD) | ||||
---|---|---|---|---|---|
Subjects: | H Social Sciences > HD Industries. Land use. Labor T Technology > TL Motor vehicles. Aeronautics. Astronautics |
||||
Library of Congress Subject Headings (LCSH): | Hybrid electric vehicles, Hybrid electric vehicles -- Batteries, Hybrid electric vehicles -- Fuel consumption, Electric power consumption, Fuel switching | ||||
Official Date: | February 2021 | ||||
Dates: |
|
||||
Institution: | University of Warwick | ||||
Theses Department: | Warwick Manufacturing Group | ||||
Thesis Type: | EngD | ||||
Publication Status: | Unpublished | ||||
Supervisor(s)/Advisor: | McGordon, Andrew | ||||
Sponsors: | TVS Motor Company | ||||
Format of File: | |||||
Extent: | 186 leaves : illustrations, charts | ||||
Language: | eng |
Request changes or add full text files to a record
Repository staff actions (login required)
View Item |