基于智能控制的转矩矢量控制系统在不同动力总成结构电动汽车上的效果对比研究

A. Parra, A. Zubizarreta, Joshué Pérez
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摘要

智能交通系统(ITS)是目前最活跃的研究领域之一,是电动汽车及其车辆动力学增强的关键课题。为此,需要开发最优的先进驾驶辅助系统(ADAS)和先进的车辆动力学控制系统。然而,由于电气化推进系统提供了多种拓扑结构(以及更高的复杂性),这项任务变得更加困难。在这种情况下,智能控制技术的使用被提议作为提供性能和灵活性的合适替代方案。为了展示智能方法的优势及其适应不同场景的能力,本研究对三种不同动力系统拓扑:前轮驱动(FWD)、后轮驱动(RWD)和四轮驱动(AWD)的电动汽车中基于智能控制的扭矩矢量(TV)算法的性能进行了比较研究。所有拓扑都使用了相同的TV方法,并且选择了滑垫测试作为评估每种拓扑横向动力学的关键操作,并使用高保真车辆模拟器进行了模拟。结果表明,相同的智能控制方法可以用于不同的拓扑结构,而无需返回其参数,从而增强了所有情况下的车辆动力学。这证明了智能方法的灵活性,因为它们减少了模型依赖性。此外,研究结果还表明,每一种结构都促进了车辆不同类型的动态行为:FWD的转向不足行为,RWD的转向过度行为,AWD的中立行为。
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A comparative study of the effect of Intelligent Control based Torque Vectoring Systems on EVs with different powertrain architectures
Intelligent Transportation Systems (ITS) is currently one of the most active research areas, being electric vehicles (EVs) and their vehicle dynamics enhancement key topics. For this purpose, the development of optimal Advanced Driver-Assistance Systems (ADAS) and Advanced Vehicle Dynamics Control Systems is required. However, as electrified propulsion systems offer multiple topologies (and higher complexity), this task becomes much more difficult. In this context, the use of intelligent control techniques has been proposed as a suitable alternative to offer both performance and flexibility.In order to demonstrate the advantages of intelligent approaches and their ability to adapt to different scenarios, this work presents a comparative study of the performance of Intelligent Control based torque vectoring (TV) algorithms in electric vehicles with three different powertrain topologies: Front Wheel Driven (FWD), Rear Wheel Driven (RWD) and Four/All Wheel Driven (AWD). The same TV approach has been used for all topologies, and a skid-pad test has been selected as a critical manoeuvre for evaluating the lateral dynamics of each topology, which has been simulated using a high fidelity vehicle simulator.Results show that the same intelligent control approach can be used for different topologies without retuning its parameters, enhancing the vehicle dynamics for all cases. This demonstrates the flexibility of intelligent approaches due to their reduced model dependency. Additionally, results show that each architecture promotes a different type of dynamic behaviour in the vehicle: understeering behaviour for the FWD, oversteering behaviour for the RWD and a neutral behaviour for the AWD.
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