scholarly journals A Systematic Review of Technologies, Control Methods, and Optimization for Extended-Range Electric Vehicles

2021 ◽  
Vol 11 (15) ◽  
pp. 7095
Author(s):  
David Sebastian Puma-Benavides ◽  
Javier Izquierdo-Reyes ◽  
Juan de Dios Calderon-Najera ◽  
Ricardo A. Ramirez-Mendoza
Keyword(s):  
Electric Vehicles ◽  
Smart Cities ◽  
Optimal Solution ◽  
Clean Energy ◽  
Control Methods ◽  
Auxiliary Power Unit ◽  
Auxiliary Power ◽  
Extended Range ◽  
Range Anxiety ◽  
Optimal Driving

For smart cities using clean energy, optimal energy management has made the development of electric vehicles more popular. However, the fear of range anxiety—that a vehicle has insufficient range to reach its destination—is slowing down the adoption of EVs. The integration of an auxiliary power unit (APU) can extend the range of a vehicle, making them more attractive to consumers. The increased interest in optimizing electric vehicles is generating research around range extenders. These days, many systems and configurations of extended-range electric vehicles (EREVs) have been proposed to recover energy. However, it is necessary to summarize all those efforts made by researchers and industry to find the optimal solution regarding range extenders. This paper analyzes the most relevant technologies that recover energy, the current topologies and configurations of EREVs, and the state-of-the-art in control methods used to manage energy. The analysis presented mainly focuses on finding maximum fuel economy, reducing emissions, minimizing the system’s costs, and providing optimal driving performance. Our summary and evaluation of range extenders for electric vehicles seeks to guide researchers and automakers to generate new topologies and configurations for EVs with optimized range, improved functionality, and low emissions.

Finding an Optimal Driving Strategy for an Electric Bus Based on Operational Data

2015 ◽  
Author(s):  
Warren Vaz ◽  
Arup K. Nandi ◽  
Umit O. Koylu
Keyword(s):  
Electric Vehicles ◽  
Management Strategy ◽  
Clean Energy ◽  
Energy Management Strategy ◽  
Multi Objective ◽  
Electric Bus ◽  
Bus Service ◽  
Battery Energy ◽  
Optimal Driving ◽  
Operational Data

One of the clean energy initiatives at Missouri S&T is an electric shuttle bus service, the Ebus. It provides valuable operational data for a fleet-type electric vehicle (EV) operating over a fixed route. The primary aim of this study is to use the daily operational data obtained from the Ebus in order to formulate an optimal driving strategy. Existing research efforts to improve EVs focus on improvements to the architecture and the energy management strategy. However, they fail to provide the driver with an optimal driving strategy leading to suboptimal use of the stored battery energy. This shortcoming was addressed here by implementing a multi-objective approach to find an optimal driving strategy for an electric bus. The driving strategy was taken to comprise two parts: a constant trip speed and an acceleration value to achieve that speed. From the operational data, the efficiency and power consumption of the electric motor were computed for different speeds. By assuming the entire trip was executed at a constant speed, the range for each speed was calculated. The speeds were ranked based on their corresponding ranges. Then, to achieve the optimal speed, the acceleration duration and energy consumption for different acceleration values were computed. The values were ranked based on the trade-off between duration and energy. The choice of driving strategy (exact speed and acceleration values) is left to the driver since different strategies would be needed for different road conditions. This multi-objective approach gives flexibility to the driver and promotes optimal use of the stored battery energy, thereby enhancing the energy efficiency and range of the Ebus. It can be easily implemented in other electric vehicles as well.

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