牵引用电动差速器

F. Pérez-Pinal, C. Nuñez, R. Alvarez, U. Cervantes, A. Emadi
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引用次数: 8

摘要

电动差速器的使用构成了车辆设计的技术进步,沿着更多的电动汽车的概念。电动差速器的优点是用更高效、更轻、更小的电动机代替松散、笨重、低效的机械传动和机械差速器,电动机通过单个齿轮或轮内电机直接连接到车轮上。到目前为止,电动差速器已被提议用于两轮和四轮车辆。尽管其长期报道的成功和可能的优势方面的灵活性和直接扭矩控制的车轮在转弯和危险的操作。电差速器在实际应用中存在几个问题;例如,控制回路的增加,计算工作量的增加和滑移。因此,本文的主要目的是提出一种简单易实现的电动差速器。所提出的策略具有线性模型和简单实现的优点。使用Matlab-Simulink进行了4 kW系统的数值模拟,该系统能够处理500 kg的质量,并在运输期间提供高达10 kW的峰值功率。
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Electric Differential for Traction Applications
The use of electric differential constitutes a technological advance of vehicle design along the concept of more electric vehicles. Electric differentials have the advantages of replacing loosy, heavy and inefficient mechanical transmission and mechanical differential with a more efficient, light and small electric motors directly coupled to the wheels via a single gear or an in-wheel motor. To date, electric differentials have been proposed for two and four wheeled vehicles. Despite its long reported success and possible advantages in terms of flexibility and direct torque control of the wheels during cornering and risky manoeuvres. Electric differential has several problems in practical applications; for instance, an increment of control loops, increase of computational effort and slip. Therefore, the main purpose of this paper is to present a simple and easy to implement electric differential. The proposed strategy has the advantages of having a linear model and a straightforward implementation. Numerical simulations using Matlab-Simulink are shown for a 4 kW system which is able to handle 500 kg mass and deliver peak power up to 10 kW during transit periods.
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