朔黄铁路POC语音调度系统服务质量测试方法研究

POC语音调度系统在朔黄铁路运营生产中发挥了重要作用,本文为朔黄POC语音调度系统设计了一种语音服务质量评价指标体系,并详细描述了各指标的计算公式和测试方法,为朔黄铁路LTE系统服务质量检测评价提供指导和支撑。     

基于光纤传感系统的德国列车实时精确定位技术

实时、精确地获取列车位置信息是保证列车安全有效运行、发挥效率、提供最佳服务的前提。而轨旁传感器将在进行高效、可靠的列车跟踪和定位方面发挥重要作用。文章介绍德国基于光纤传感系统的列车实时精确定位技术,这是一种全新的解决方案,具有独特的优势和可能性。     

考虑空车调配协调的货物列车开行方案优化研究

为实现空车调配与货物列车开行方案协调优化，结合基本运行图架构与车流径路，构建货运时空服务拓展网络。考虑配空与装卸取送、集编发等环节的时间接续要求，节点与区段不对流空车要求，以重车流全程运送与空车配送等广义总费用最少为目标，建立整数规划弧路模型。针对既有算法设计局限性，结合重车或空车配空的时间接续要求，提出将不同的 k 短路重车流方案与空车配空方案相关联的改进可行解构造方法，设计混合差分进化求解算法。实例研究表明，考虑空车调配进行重车、空车流组织协调优化，能够减少空车走行费用，及时满足装车需求，有效保证作业车流配合中转车流集结编组及时挂线，提高方案可实施性。     

LNG码头应急通道与应急锚地研究

本文针对LNG应急逃离情况以及国内LNG应急锚地使用现状,总结分析国内、外LNG应急锚地布置情况;结合江苏滨海LNG码头通航条件,提出LNG应急通道及应急锚地三种布置方案,通过操船模拟试验论证比选并得出结论,供类似工程参考。     

HXD1型机车自动驾驶系统设计与应用

主要介绍HXD1型交流传动电力机车的自动驾驶系统方案设计与应用情况,以机车改动最小、成本最低为原则,通过加装自动驾驶系统设备、通信及供电线缆实现自动驾驶功能。通过机车自动系统的成功运用,降低了人工劳动强度,杜绝了人为失误因素,提升了机车操纵水平和操纵一致性。     

城市轨道交通全自动运行线路在无人值守模式下的应急处置

基于不同的场景,详细阐述了无人值守模式下全自动运行线路的应急处置方法、区间疏散方式及救援方式。结合专门的自动应急或远程应急功能,使无人值守全自动运行线路应急处置能兼顾运营效率和安全,避免列车迫停区间。建议做好多职能队员的相关培训工作,并合理选择列车自动运行控制系统的应急功能。     

浅谈沿海航行船舶应急演练存在的问题与改进措施

在日常船舶安全检查中,发现应急训练与演习存在一些问题,这些问题影响了船员应急反应能力的提升,带来了船舶安全隐患。根据国内航行货船应急训练与演习的要求,提出改进建议,旨在提高船员对应急训练与演习的认识,加强日常训练与演习,不断提升应急反应能力,以保障船舶和船员生命安全。     

LED灯具在高速列车照明系统中的应用

随着我国高速铁路事业的发展,旅客对车内照明环境品质的要求越来越高,在我国高速列车照明设计中广泛采用LED灯具作为光源。通过对高速动车组车载灯具与25T型列车传统车载灯具的测试对比,总结出LED灯具在发光效率等方面相对于传统灯具的优势,为高速动车组室内照明设计提供依据。     

Modelling,simulation and applications of longitudinal train dynamics

ABSTRACT

Significant developments in longitudinal train simulation and an overview of the approaches to train models and modelling vehicle force inputs are firstly presented. The most important modelling task, that of the wagon connection, consisting of energy absorption devices such as draft gears and buffers, draw gear stiffness, coupler slack and structural stiffness is then presented. Detailed attention is given to the modelling approaches for friction wedge damped and polymer draft gears. A significant issue in longitudinal train dynamics is the modelling and calculation of the input forces – the co-dimensional problem. The need to push traction performances higher has led to research and improvement in the accuracy of traction modelling which is discussed. A co-simulation method that combines longitudinal train simulation, locomotive traction control and locomotive vehicle dynamics is presented. The modelling of other forces, braking propulsion resistance, curve drag and grade forces are also discussed. As extensions to conventional longitudinal train dynamics, lateral forces and coupler impacts are examined in regards to interaction with wagon lateral and vertical dynamics. Various applications of longitudinal train dynamics are then presented. As an alternative to the tradition single wagon mass approach to longitudinal train dynamics, an example incorporating fully detailed wagon dynamics is presented for a crash analysis problem. Further applications of starting traction, air braking, distributed power, energy analysis and tippler operation are also presented.     

Dynamic simulation of train–truck collision at level crossings

Trains crashing onto heavy road vehicles stuck across rail tracks are more likely occurrences at level crossings due to ongoing increase in the registration of heavy vehicles and these long heavy vehicles getting caught in traffic after partly crossing the boom gate; these incidents lead to significant financial losses and societal costs. This paper presents an investigation of the dynamic responses of trains under frontal collision on road trucks obliquely stuck on rail tracks at level crossings. This study builds a nonlinear three-dimensional multi-body dynamic model of a passenger train colliding with an obliquely stuck road truck on a ballasted track. The model is first benchmarked against several train dynamics packages and its predictions of the dynamic response and derailment potential are shown rational. A geometry-based derailment assessment criterion is applied to evaluate the derailment behaviour of the frontal obliquely impacted trains under different conditions. Sensitivities of several key influencing parameters, such as the train impact speed, the truck mass, the friction at truck tyres, the train–truck impact angle, the contact friction at the collision zone, the wheel/rail friction and the train suspension are reported.