基于弓网电弧动态模型的高速列车弓网电弧产生机理

分析了高速列车弓网电弧产生的机理,结合受电弓和接触网间的离线时间、材料缺陷、电腐蚀等问题,解析了弓网电弧与高速列车安全的关联机制。依据电弧理论的动态模型算法,推导了Cassie模型和Mayr模型的理论公式,并论述了这两种模型的适用条件和应用范围。提出了高速列车弓网电弧方面目前仍存在的问题及未来电弧研究的展望。     

机车车辆和列车检测系统兼容性标准制定历史及若干问题分析

机车车辆和列车检测系统的兼容性涉及行车安全,欧洲TSI中对其有明确的要求和配套标准,近年来中国国内也制定了类似标准,但以修改采用IEC或EN相关标准为主,总体上系统性研究较为缺乏。通过文献研究法,搜集整理了国内外机车车辆和列车检测系统兼容性标准和相关欧洲研究项目等资料,对标准的演进和完善过程进行了梳理和总结,并选取当前标准制定和运用中的若干问题进行分析。历经20年,欧洲包括EN 50238系列和EN 50617系列的兼容性标准体系已经基本建成,TSI中关于欧洲频率管理(FrM)的开口项也已初步关闭。IEC仅针对EN 50238第1部分制定了IEC 62427标准,而中国现行相关国家标准并不完善。建议立足中国铁路特点开展相关理论研究和系统测试,确定符合我国实际的干扰电流限值,完善相关标准体系。     

受限状态下的高速列车迭代学习控制方法研究

针对受限状态下的高速列车自动驾驶系统的跟踪控制问题,基于列车动力学模型,提出一种带饱和函数的迭代学习控制算法。根据Lyapunov稳定性原理,利用列车运行过程中的状态偏差,推导出基于迭代学习控制的列车自动运行控制律。建立类Lyapunov的复合能量函数,通过在迭代域的差分,证明了其差分负定性和有界性,所设计的算法能够控制列车在迭代域对期望运行轨迹达到渐近收敛。采用本文提出的迭代学习控制算法对列车的跟踪性能进行验证,并与PID控制和D型迭代学习控制算法进行比较,结果表明:相较于其他两种算法,本文提出的算法在第3次迭代中就能控制列车精确跟踪期望轨迹,说明算法具有较快的收敛速度和较高的跟踪精度,且能够将控制输入约束在允许范围内。     

中尼跨境铁路工程地质环境特征及主要工程地质问题研究

中尼跨境铁路是首条穿越喜马拉雅山脉的铁路,位于印度板块与欧亚板块直接碰撞、拼合的作用带内,其地形、地质条件和自然环境极其复杂,是世界铁路建设史上难度及风险极大的铁路工程。通过分析总结工程地质环境特征,提出影响铁路建设的主要工程地质问题。研究表明:中尼跨境铁路工程地质环境特征呈典型的"六极四高"特征,存在极高地应力下的软岩大变形、硬岩岩爆问题,深大活动断裂的工程地质效应问题,高烈度地震问题,高地温热害问题,边坡稳定性问题,泥石流水毁问题及其他工程地质问题。建议采用"科学研究作先导,先进勘察技术为手段,常规调查与勘探是基础"的勘察设计理念,针对性开展中尼跨境铁路主要工程地质问题分布规律、对铁路工程影响、综合选线技术、工程措施等关键技术研究。     

考虑客流空间分布的地铁列车节能时刻表优化方法

客流变化引起的列车质量变化是影响地铁列车能耗与节能运行的重要因素之一. 本文考虑地铁线路客流空间分布差异，研究耗散型再生制动能利用方式下的列车节能时刻表优化方法. 结合各区间载荷差异和列车运动方程，建立以净能耗最小为目标的时刻表优化模型，通过适度优化计划停站时间、区间运行时间和折返时间协同多列车牵引、巡航、惰行和制动过程的时空分布，设计二分法和粒子群算法对模型求解. 以北京地铁某线路进行实例研究，结果表明，优化模型能有效协同多列车的节能运行，考虑客流空间分布差异比假定列车载荷为常数能进一步提升节能效果.     

地铁运行图质量指标评价研究

通过对地铁运行图质量指标体系的研究分析,以广州地铁为例,阐述了三大指标对列车运行图的评价意义,期望给同行提供借鉴.     

高职英语分级教学利弊分析

《高职高专教育英语课程教学基本要求》是实施分级教学的指导方针,Krashen的输入假设理论是分级教学的重要理论依据。本文陈述了分级教学的实施过程,分析了高职分级教学的优势和存在的问题,并为以后教学提出了合理的建议,以期高职教学达到最佳效果。     

Modelling and validation of coupled high-speed maglev train-and-viaduct systems considering support flexibility

This study presents a more realistic modelling of the maglev-based high-speed railway line in Shanghai, China. Focus is placed on an accurate simulation of the two subsystems: the train subsystem including the magnets and the viaduct subsystem including the modular function units of the rails. The electromagnet force–air gap model with a proportional-derivative (PD) controller is adopted to simulate the interaction between the maglev train via its electromagnets and the viaduct via its modular function units. The flexibilities of the rails, girders, piers and associated elastic bearings are all considered in the modelling of the viaduct subsystem to investigate their effects on an interaction between the two subsystems. By applying the proposed model to the Shanghai maglev line, the essential characteristics of the coupled system can be duly captured. The accuracy and effectiveness of the proposed approach are then validated by comparing the computed dynamic responses and frequencies with the measurement results. It is confirmed that the proposed modelling with a detailed simulation of the magnets and modular function units can duly account for the dynamic interaction between the train and viaduct systems. Moreover, the effects of the inclusion of the flexibilities of the rails, girders and elastic supports to the response of the coupled system are respectively investigated, the results of which prove that their involvements are essential to the accurate prediction of the response of the coupled maglev train–viaduct system.     

Train routing and timetabling problem for heterogeneous train traffic with switchable scheduling rules

This paper proposes a mathematical model for the train routing and timetabling problem that allows a train to occasionally switch to the opposite track when it is not occupied, which we define it as switchable scheduling rule. The layouts of stations are taken into account in the proposed mathematical model to avoid head-on and rear-end collisions in stations. In this paper, train timetable could be scheduled by three different scheduling rules, i.e., no switchable scheduling rule (No-SSR) which allows trains switching track neither at stations and segments, incomplete switchable scheduling rule (In-SSR) which allows trains switching track at stations but not at segments, and complete switchable scheduling rule (Co-SSR) which allows trains switching track both at stations and segments. Numerical experiments are carried out on a small-scale railway corridor and a large-scale railway corridor based on Beijing–Shanghai high-speed railway (HSR) corridor respectively. The results of case studies indicate that Co-SSR outperforms the other two scheduling rules. It is also found that the proposed model can improve train operational efficiency.     

Pneumatic train brake simulation method

The design of new pneumatic brakes for rail vehicles or improvements of existing ones can be made better or more efficient by the use of a simulation method. This paper gives a general presentation of the author’s modelling methods used for solving problems relating to railway pneumatic brakes. The brake models in this paper (slightly different from those of other authors) take into account air-wave phenomena including air viscosity, the influence of the brake pipe branches, heat transfer in the brake pipes and reservoirs, air flows in the brake valves and the dynamics of moving mechanical parts. For various simulation purposes, separate partial models with different levels of accuracy were created. Various verifications and identifications of the models were performed with the use of train brake testing facilities, including both in-house and other test stands. A variety of examples of simulation results are presented here.