Multiphysic model-based design and fuel consumption optimization of a series-hybrid electric vehicle (SHEV)

Tesauro, Giovanni (2024) Multiphysic model-based design and fuel consumption optimization of a series-hybrid electric vehicle (SHEV). [Laurea magistrale], Università di Bologna, Corso di Studio in Ingegneria meccanica [LM-DM270], Documento full-text non disponibile
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Abstract

The growing interest in the decarbonization process has led to a rapid growth of electrification strategies in the automotive industry. In particular, OEMs are pushing towards the development and production of efficient hybrid vehicles as a transition solution towards the deployment of electric vehicles. Indeed, research on energy management control strategies for hybrid vehicles is exploding in popularity. In this context, this thesis focuses on the development of a high-performance series-hybrid electric vehicle model, developed on Matlab Simulink environment, in order to simulate the powertrain and test and optimize different control strategies with the aim of minimizing fuel consumption. After a careful benchmarking analysis, which was useful for dimensioning the components in an initial map-based modelling phase, the final goal of the thesis was to implement two types of control strategy (SOC rule-based and ECMS optimization-based) for energy management and implementation of the system components. In addition, the vehicle model is able to switch from one driving mode to another: the cruise mode forces the internal combustion engine to operate in such a way as to minimize fuel consumption; during the sport mode, the internal combustion engine is able to operate at torque and RPM values that guarantee the best possible engine sound quality. Based on the demand for sport mode, a virtual gear shift logic has been implemented, considering that the engine is not connected to the traction. Several models, characterized by increasing levels of complexity, are simulated in quasi-dynamic mode, choosing the correct simulation time step to capture all vehicle dynamics. The driving cycle input of such forward simulator are the WLTP homologation cycle, the range driving cycle and the Nϋrburgring track driving cycle. Finally, the selection of the best control strategy is achieved considering the fuel consumption and the vehicle range.

Abstract
Tipologia del documento
Tesi di laurea (Laurea magistrale)
Autore della tesi
Tesauro, Giovanni
Relatore della tesi
Correlatore della tesi
Scuola
Corso di studio
Indirizzo
Macchine a fluido
Ordinamento Cds
DM270
Parole chiave
model-based design,Simulink,Simscape,Matlab,Series-Hybrid Electric Vehicle,Fuel consumption minimization,ECMS,Rule-based optimization,Virtual gear shift logic,Engine sound,homologation cycle,WLTP,Range test
Data di discussione della Tesi
24 Luglio 2024
URI

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