基于因子分析与AHP的高速列车乘坐舒适度评价模型与实证分析

针对目前舒适度研究偏重于列车运行物理指标层面的现状,结合人机工程学、环境与行为心理学等相关理论,提出了综合满足旅客乘坐需求、生理感受与心理感受的高速列车广义舒适度的概念。在对北京至四方的铁路线运行的CRH2型动车组745位旅客进行问卷调查的基础上,通过因子分析对指标进行降维,利用AHP构建乘坐舒适度评价模型,得出舒适度影响因素的权重,并提出改进建议:1.细化列车振动、噪声与照明舒适度评价指标;2.优化座椅休息、就餐、娱乐等功能设计;3.进一步调控车厢温度、湿度与空气质量。该模型的建立为我国高速列车乘坐舒适度研究提供了理论依据。     

轮毂电机驱动电动汽车3种构型的平顺性分析

针对轮毂电机驱动电动汽车3种构型,对其平顺性问题展开研究。分别采用滤波白噪声方法和三角形凸块描述随机路面激励和脉冲路面激励。建立了轮毂电机驱动电动汽车3种构型的振动模型,确定了相应的平顺性评价指标。在随机路面和脉冲路面下,采用Matlab/Simulink仿真了轮毂电机驱动电动汽车3种构型的平顺性。研究结果表明,具有吸振结构的构型2和具有悬置结构的构型3与传统悬架的构型1相比,降低了轮毂电机驱动电动汽车随机路面和脉冲路面的平顺性评价指标。     

轿车乘坐方式探讨

分析研究了轿车内室空间布局,提出轿车内室有2种乘坐方式的设计构想,既能达到普通乘坐方式舒适的要求,又能在乘员需要方便交流的情况下,有一个更合适的乘坐方式。     

基于ADAMS／Car Ride车辆平顺性仿真研究

以虚拟样机技术进行车辆平顺性仿真研究．建立了基于ADAMS／Car Ride的多体动理学模型，通过虚拟四柱试验台对模型进行仿真试验。仿真结果表明，ADAMS／Car Ride可方便地进行路面功率谱密度响应仿真试验，所建立的包含虚拟四柱试验台的整车模型可深入进行车辆平顺性研究。     

Decoupled 3D moment control using in-wheel motors

Vehicles equipped with in-wheel motors are being studied and developed as a type of electric vehicle. Since these motors are attached to the suspension, a large vertical suspension reaction force is generated during driving. Based on this mechanism, this paper describes the development of a method for independently controlling roll and pitch as well as yaw using driving force distribution control at each wheel. It also details the theoretical calculation of a method for decoupling the dynamic motions. Finally, it describes the application of these 3D dynamic motion control methods to a test vehicle and the confirmation of the performance improvement.     

Roll- and pitch-plane-coupled hydro-pneumatic suspension. Part 2: dynamic response analyses

In the first part of this study, the potential performance benefits of fluidically coupled passive suspensions were demonstrated through analyses of suspension properties, design flexibility and feasibility. In this second part of the study, the dynamic responses of a vehicle equipped with different configurations of fluidically coupled hydro-pneumatic suspension systems are investigated for more comprehensive assessments of the coupled suspension concepts. A generalised 14 degree-of-freedom nonlinear vehicle model is developed and validated to evaluate vehicle ride and handling dynamic responses and suspension anti-roll and anti-pitch characteristics under various road excitations and steering/braking manoeuvres. The dynamic responses of the vehicle model with the coupled suspension are compared with those of the unconnected suspensions to demonstrate the performance potential of the fluidic couplings. The dynamic responses together with the suspension properties suggest that the full-vehicle-coupled hydro-pneumatic suspension could offer considerable potential in realising enhanced ride and handling performance, as well as improved anti-roll and anti-pitch properties in a very flexible and energy-saving manner.     

运用车辆动态模拟装置提高东海道新干线列车的乘坐舒适性

介绍了车辆动态模拟装置在评价车辆乘坐舒适性方面的应用情况,并阐述了车辆动态模拟装置在车辆部件研发过程中的重要作用.     

基于欧雷准则的某纯电动车悬架刚度优化匹配研究

在车型开发前期对悬架系统刚度、阻尼进行合理的优化匹配,不仅能缩短整车开发周期,同时还能提升整车性能,基于欧雷准则,以车辆二自由度模型为基础研究了前、后悬架刚度优化匹配的方法,并在某电动车动力学性能开发前期得以应用,通过实车试验与优化结果对比充分验证了该方法具有一定的工程应用价值,且能够大大缩短样车开发周期。     

Dynamic model for ride comfort evaluations of the rubber-tired light rail vehicle

The dynamic model was developed to evaluate vibration accelerations and ride comforts during the running of the Korean-standardised rubber-tired light rail vehicle. Ride comfort indexes were analysed and tested in accordance with UIC 513R by using the dynamic model and the actual vehicle in the test track. Based on the comparisons between analysis results and test results, the validity of the developed dynamic model was evaluated. It was verified whether or not the developed Korean-standardised rubber-tired light rail vehicle met the specified target specification on ride comfort. In addition, the influence of the wearing of guide wheels on ride comfort was estimated.     

Field measurements of the evolution of wheel wear and vehicle dynamics for high-speed trains

This investigation demonstrates the wheel wear evolution and related vehicle dynamics of high-speed trains with an operating distance (OD) of around two million kilometres. A long-term experimental test lasting two years was conducted to record the wheel profiles and structural vibrations of various trainsets. The wheel wear, namely the profile shape, worn distribution and wheelset conicity, is investigated for several continuous reprofiling cycles. Typical results are illustrated for the stability analysis, and the ride quality is examined with increasing OD. In addition, the vibration transition characteristics between suspensions are investigated in both the time and frequency domains. The experiments show that the dominant wear concentrates on the nominal rolling radius, and the wear rate increases with OD because of the surface softening resulting from the loss of wheel material. The vibration of structural components is aggravated by the increase of the equivalent conicity of the wheelset, which rises approximately linearly with the wheel wear and OD. High-frequency vibrations arise in the bogie and car body related to the track arrangement and wheel out-of-roundness, causing the ride comfort to worsen significantly. Additionally, the system vibration characteristics are strongly dependent on the atmospheric temperature. Summaries and conclusions are obtained regarding the wheel wear and related vehicle dynamics of high-speed trains over long operating times and distances.