Abstract
The increased concern over global climate change and lack of long-term sustainability of fossil fuels in the projected future has prompted further research into advanced alternative fuel vehicles to reduce vehicle emissions and fuel consumption. One of the primary advanced vehicle research areas involves electrification and hybridization of vehicles. As hybrid-electric vehicle technology has advanced, so has the need for more innovative control schemes for hybrid vehicles, including the development and optimization of hybrid powertrain transmission shift schedules. The hybrid shift schedule works in tandem with a cost function-based torque split algorithm that dynamically determines the optimal torque command for the electric motor and engine. The focus of this work is to develop and analyze the benefits and limitations of two different shift schedules for a position-3 (P3) parallel hybrid-electric vehicle. a traditional two-parameter shift schedule that operates as a function of vehicle accelerator position and vehicle speed (state of charge (SOC) independent shift schedule), and a three-parameter shift schedule that also adapts to fluctuations in the state of charge of the high voltage batteries (SOC dependent shift schedule). The shift schedules were generated using an exhaustive search coupled with a fitness function to evaluate all possible vehicle operating points. The generated shift schedules were then tested in the software-in-the-loop (SIL) environment and the vehicle-in-the-loop (VIL) environment and compared to each other, as well as to the stock 8L45 8-speed transmission shift schedule. The results show that both generated shift schedules improved upon the stock transmission shift schedule used in the hybrid powertrain comparing component efficiency, vehicle efficiency, engine fuel economy, and vehicle fuel economy.
Highlights
The effort to reduce tailpipe emissions from transport vehicles has grown in recent years
The focus of this work is to develop and analyze the benefits and limitations of two different shift schedules for a position-3 (P3) parallel hybrid-electric vehicle. a traditional two-parameter shift schedule that operates as a function of vehicle accelerator position and vehicle speed (state of charge (SOC) independent shift schedule), and a three-parameter shift schedule that adapts to fluctuations in the state of charge of the high voltage batteries (SOC dependent shift schedule)
If accelerator pedal percentage (APP) is held constant at 0%, or no driver accelerator pedal input, and the vehicle is increasing in speed, the shift schedule commands upshifts much sooner to decrease the torque capacity of the engine at the wheels
Summary
The effort to reduce tailpipe emissions from transport vehicles has grown in recent years. One area of improvement has been the effort to electrify vehicles to varying degrees, including development of mild-hybrid systems to fully electrified battery electric vehicles (BEV). Hybrid electric vehicles (HEV) offer advantages over both the internal combustion engine (ICE) and BEV architectures. To successfully operate HEVs, which are powered by two independent energy sources, a control strategy to split power usage from both powertrains is required. The reasons for developing a control strategy include controlling the state of charge (SOC) of the high voltage battery in order to maintain consistent power availability to the wheels for the driver and to optimize the consumption of energy and reduce production of tailpipe emissions, but are not limited to these constraints
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