高速铁路轮轨噪声预测分析

基于高速铁路轮轨噪声机理,对高速铁路轮轨滚动噪声预测方法进行分析。建立高速铁路轮轨噪声预测分析模型,为轮轨噪声的控制提供必要的依据。在探讨列车—轨道相互作用关系、轮轨表面粗糙度、轮轨接触滤波、噪声辐射比、轮轨系统噪声辐射、地面的声反射等问题的基础上,对我国快速客运专线的轮轨噪声进行了数值仿真预测。给出轮轨噪声的频谱特性、距离衰减特性及随运行速度的变化规律。     

基于dSPACE半实物仿真平台的永磁同步电动机数学模型的实现

介绍了永磁同步电机的数学模型以及基于MATLAB/Simulink中的S函数进行的离线仿真和基于dSPACE平台的半实物仿真.离线仿真和半实物仿真结果都表明了模型和S函数的正确性、有效性.通过半实物仿真,突出了ControlDesk在实时仿真中的优越性.     

我国筑路机械行业迎接“入关”浅议

本文分析了我国重返关贸总协定(简称“入关”)后筑路机械行业的市场供求现状,提出了筑路机械工业为迎接“入关”挑战在经济规模、产业结构、技术质量、管理营销、售后服务等方面的看法。     

铁道车辆轮重测定仪检定装置的研制

为满足铁路货场铁路车辆轮重测定仪的现场检测与维修工作,研制了体积小、重量轻、结构简单的LJ-B型铁路车辆轮重测定仪检定装置。从研制目标、系统结构与原理、研制方案和技术难点及实际运用情况等方面,详细介绍LJ-B型铁路车辆轮重测定仪检定装置。     

基于图形化编程语言的列车人机界面设计

详细介绍一种适用于城市地铁车辆人机界面的设计方案.通过对比分析,选择功能强大的x86架构硬件平台、开源但稳定性好的Linux系统及图形化编程语言LabVIEW.组建并论述人杌界面的整体架构和各个界面的对应功能,实验结果验证了系统设计方案的正确性和优越性.     

CRH2010A综合检测车测力车轮与钢轨滚动接触弹塑性分析

运用非线性有限元分析软件ABAQUS,考虑通过直线、曲线线路和道岔3种工况,建立CRH2010A综合检测车的测力车轮与钢轨的三维滚动接触有限元模型,进行不同工况下测力车轮与钢轨的滚动接触特性及车轮辐板和轴毂的受力分析。结果表明:测力车轮的滚动接触特性与动车车轮相似;通过直线线路且轮对横移量为8mm时,产生轮缘效应,车轮磨损加剧;通过曲线线路时,左侧车轮与钢轨出现两点接触中心区;通过道岔时,左侧车轮与长心轨均发生塑性变形,车轮和钢轨的磨耗加剧;轴毂的过盈连接对轮轨接触特性的影响,远小于其对轴毂连接区域和辐板加工区域应力的影响;在这3种工况下测力车轮均满足静强度要求。     

列车提速对线路的动力影响研究与对策

列车提速是我国铁路实施的具有战略意义的重大决策。由于提速是在既有线眩进行的，提速后机车车辆对线路结构的动力影响将不可避免地增强，给轨道结构强度和线路日常养护维修工作带来不利影响、文中运用车辆一轨道耦合动力学理论，以及车轮擦伤对线路的动力影响等，进行了较细致的分析研究，在此基础上提出了解决这些问题的基本对策。     

The effect of wheel set gyroscopic action on the hunting stability of high-speed trains

This study explores the effects of wheel set gyroscopic action on hunting stability by calculating linear and nonlinear critical speeds. First, a dynamic model for a high-speed vehicle with 23 degrees of freedom is developed by considering wheel set gyroscopic action. The linear and nonlinear critical speeds are calculated by eigenvalue analysis and drawing a bifurcation map, respectively. Two computer programs for linear and nonlinear stability analysis are developed. Second, based on an actual high-speed vehicle in China, the effects of wheel set gyroscopic action on hunting stability are quantitatively investigated using computer simulation. Furthermore, the difference between the effects of gyroscopic moments about the x-axis and z-axis is discussed. The results show that the moment about the x-axis is harmful to hunting stability, but the moment about the z-axis is beneficial to hunting stability. However, the integrated effect of these two moments can enhance the critical speeds and suppress the hunting motion.     

New methodology for fast prediction of wheel wear evolution

In railway applications wear prediction in the wheel–rail interface is a fundamental matter in order to study problems such as wheel lifespan and the evolution of vehicle dynamic characteristic with time. However, one of the principal drawbacks of the existing methodologies for calculating the wear evolution is the computational cost. This paper proposes a new wear prediction methodology with a reduced computational cost. This methodology is based on two main steps: the first one is the substitution of the calculations over the whole network by the calculation of the contact conditions in certain characteristic point from whose result the wheel wear evolution can be inferred. The second one is the substitution of the dynamic calculation (time integration calculations) by the quasi-static calculation (the solution of the quasi-static situation of a vehicle at a certain point which is the same that neglecting the acceleration terms in the dynamic equations). These simplifications allow a significant reduction of computational cost to be obtained while maintaining an acceptable level of accuracy (error order of 5–10%). Several case studies are analysed along the paper with the objective of assessing the proposed methodology. The results obtained in the case studies allow concluding that the proposed methodology is valid for an arbitrary vehicle running through an arbitrary track layout.     

Further study on the wheel–rail impact response induced by a single wheel flat: the coupling effect of strain rate and thermal stress

A comprehensive dynamic finite-element simulation method was proposed to study the wheel–rail impact response induced by a single wheel flat based on a 3-D rolling contact model, where the influences of the structural inertia, strain rate effect of wheel–rail materials and thermal stress due to the wheel–rail sliding friction were considered. Four different initial conditions (i.e. pure mechanical loading plus rate-independent, pure mechanical loading plus rate-dependent, thermo-mechanical loading plus rate-independent, and thermo-mechanical loading plus rate-dependent) were involved into explore the corresponding impact responses in term of the vertical impact force, von-Mises equivalent stress, equivalent plastic strain and shear stress. Influences of train speed, flat length and axle load on the flat-induced wheel–rail impact response were discussed, respectively. The results indicate that the maximum thermal stresses are occurred on the tread of the wheel and on the top surface of the middle rail; the strain rate hardening effect contributes to elevate the von-Mises equivalent stress and restrain the plastic deformation; and the initial thermal stress due to the sliding friction will aggravate the plastic deformation of wheel and rail. Besides, the wheel–rail impact responses (i.e. impact force, von-Mises equivalent stress, equivalent plastic strain, and XY shear stress) induced by a flat are sensitive to the train speed, flat length and axle load.