Abstract
This paper presents an integrated optimization framework of sizing and energy management for four-wheel-independently-actuated electric vehicles. The optimization framework consists of an inner and an outer layer that are responsible for energy management, i.e., torque allocation, and powertrain parameter optimizations. The optimal torque allocation in the inner layer is achieved via the dynamic programming (DP) method while the desirable powertrain parameters in the outer layer are pursued based on the exhaustive method. In order to verify the proposed optimization framework, two driving cycles are constructed to represent the comprehensive and realistic driving conditions. One cycle is built by combining six typical driving cycles, which cover urban, high-way and rural driving styles to enhance representativeness. The other one is synthesized using the Markov chain method based on a vast quantity of real-time operating data of electric vehicles in Beijing. Simulation results demonstrate that the proposed strategy decreases the power consumption by 15.1% and 13.3%, respectively, in the two driving cycles, compared to the non-optimal, even-torque-allocation strategy.
Highlights
The dynamic programming (DP) algorithm described in the study is adopted for optimal power allocation; Optimal sizing + baseline control (OSBC)
Is used, and the sizes of both the front- and rear-axle motors are left for optimization; Optimal sizing + optimal control (OSOC)
This paper proposes a combined sizing and control optimization for a four-wheelindependently-actuated electric vehicle (FWIA electric vehicles (EVs))
Summary
The rapid development of electric vehicles (EVs) represents a paradigm transition towards green and sustainable transportation [1,2,3]. Four in-wheel motors are respectively installed in each wheel hub and can be collaboratively controlled for vehicle propulsion [6,7]. This distributed powertrain structure significantly simplifies the drivetrain by eliminating the transmission shaft, differential and final drive [8]. The extent to which the vehicle performance can be enhanced is strongly dependent on the powertrain sizing, including the battery pack and in-wheel motors, as well. It is imperative to developing a framework that simultaneously considers powertrain sizing and energy management synthesis with the aim of improving the vehicle efficiency [9]. It is significant to increase the driving range per charge and help reduce the “range anxiety” of consumers
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