基于模糊逻辑的电动汽车制动能量回馈系统

分析了电动汽车制动能量回馈的特点，针对电动汽车制动能量回馈时强鲁棒性的需求，设计了一种基于Sugeno模糊逻辑的制动能量回馈系统，以满足能量回馈的要求，该回馈系统提高了整车的制动性能以及续驶里程，也使整车的动力性、安全性和舒适性达到较好的平衡，文章同时估算了这种控制策略的能量回收效率。经仿真和实际测试，结果表明所提策略满足总体设计的性能指标要求。     

盘式制动器15次循环制动温度计算

本文针对盘式制动器，提出了15次循环制动的温升热力学模型，并利用有限差分法进行了实车计算，结果表明方法是可行的，可为制动器与整车的匹配设计提供参考。     

基于FMECA故障分析的高速动车组制动系统RAMS研究

高速动车组制动系统RAMS管理能够保证车辆在其全寿命周期内达到其功能要求。文章以CRH2型高速动车组制动系统为对象建立了可靠性模型,利用FMECA方法,系统地分析了制动系统的故障模式影响及危害性,并将其可能的故障模式按严重程度分类,以便采取改进措施。     

Design of rollover prevention controller with linear matrix inequality-based trajectory sensitivity minimisation

This paper presents a method to design a rollover prevention controller for vehicle systems. The vehicle rollover can be prevented by a controller that minimises the lateral acceleration and the roll angle. Rollover prevention capability can be enhanced if the controlled vehicle system is robust to the variation of the height of the centre of gravity and the speed of the vehicle. For this purpose, a robust controller is designed with linear matrix inequality-based trajectory sensitivity minimisation. Differential braking and active suspension are adopted as actuators that generate yaw and roll moments, respectively. The newly proposed method is shown to be effective in preventing rollover by the simulation on a non-linear multibody dynamic simulation software, CarSim^®.     

北京地铁新线100km/h车辆热容量问题分析

对北京地铁新线100 km/h车辆热容量问题进行了分析,对4种基础制动装置的配置方案进行了探讨。     

Limit braking of a high-performance motorcycle

A mathematical-model-based study of the limit braking of a high-performance motorcycle and rider is described. Front and rear brakes are operable independently. A dry road and high friction are presumed, such that full braking of the front wheel would lead to an overturn or ‘stoppie’ in colloquial parlance. Effective braking needs to maintain some loading on the rear wheel. A planar but otherwise detailed system model is set up and braking strategies for front and rear are devised. Parameters of the braking control schemes are derived with the help of an optimisation process, minimising the final speed in braking from high speed over a fixed time interval. Simulation results are examined critically and the strategy is developed until efficient use of the friction available is made. The nature of optimal braking events is demonstrated. The influences of slipper-clutch torque setting and the rear-tyre target load chosen are shown.     

AEB与可逆预紧安全带联合作用下乘员保护效果研究

针对自动紧急制动系统(AEB)导致乘员在碰撞前出现身体前倾和离位的现象,提出了使用可逆预紧安全带可以改善该现象,并且研究了在AEB和可逆预紧的联合作用下对不同坐姿乘员的保护效果。建立了某车型驾驶员侧包括正常坐姿和四种离位坐姿的约束系统仿真模型,并进行了验证。以五种坐姿乘员为研究对象,分别对比无AEB无可逆预紧,有AEB无可逆预紧,以及有AEB有可逆预紧三种情况下乘员的位移和损伤。结果表明:在只有AEB的作用下,碰撞发生后会增加乘员的离位,当初始坐姿为离位状态时更加严重,导致局部损伤增加,尤其是胸部损伤。在AEB和可逆预紧的联合作用下,各种坐姿下由AEB导致的离位得到改善,对于前移直立坐姿OOP02和左倾坐姿OOP03还能起到纠正初始离位的作用,各部位损伤指标和损伤风险也明显降低。     

Dynamics of railway wagons subjected to braking torques on defective tracks

It is well known that track defects cause profound effects to the dynamics of railway wagons; normally such problems are examined for cases of wagons running at a constant speed. Brake/traction torques affect the speed profile due to the wheel–rail contact characteristics but most of the wagon–track interaction models do not explicitly consider them in simulation. The authors have recently published a model for the dynamics of wagons subject to braking/traction torques on a perfect track by explicitly considering the pitch degree of freedom for wheelsets. The model is extended for cases of lateral and vertical track geometry defects and worn railhead and wheel profiles. This paper presents the results of the analyses carried out using the model extended to the dynamics of wagons containing less ideal wheel profiles running on tracks with geometry defects and worn rails.     

A novel fuzzy logic correctional algorithm for traction control systems on uneven low-friction road conditions

The traction control system (TCS) might prevent excessive skid of the driving wheels so as to enhance the driving performance and direction stability of the vehicle. But if driven on an uneven low-friction road, the vehicle body often vibrates severely due to the drastic fluctuations of driving wheels, and then the vehicle comfort might be reduced greatly. The vibrations could be hardly removed with traditional drive-slip control logic of the TCS. In this paper, a novel fuzzy logic controller has been brought forward, in which the vibration signals of the driving wheels are adopted as new controlled variables, and then the engine torque and the active brake pressure might be coordinately re-adjusted besides the basic logic of a traditional TCS. In the proposed controller, an adjustable engine torque and pressure compensation loop are adopted to constrain the drastic vehicle vibration. Thus, the wheel driving slips and the vibration degrees might be adjusted synchronously and effectively. The simulation results and the real vehicle tests validated that the proposed algorithm is effective and adaptable for a complicated uneven low-friction road.