海洋石油工作船挂、解拖作业安全影响因素分析

从海洋石油工作船挂、解拖的实际作业流程出发,根据海上交通工程系统理论,将作业安全的影响因素划分为人员-船舶-作业环境3大类,采用层次分析法,找出3大类因素中相对主要的因素,得出其对作业安全的影响程度,从而有针对性地为选择安全作业环境、提供安全作业条件、实施安全管理等提供理论参考。     

旋转式防撞护栏安全性能典型特征分析

分析旋转式防撞护栏的典型防护机理,进行实车碰撞试验检验,将结果与其他护栏的碰撞试验结果进行对比,揭示其典型安全性能特征,研究结果可为工程项目护栏设计提供参考.     

平面交叉口港湾式左转车道安全设计

在平面交叉口交通事故中,与左转相关的事故占较大比例,而设置港湾式左转车道,可有效改善平交路口的交通安全状况。分析左转车辆对交叉口安全性的影响,确定设置港湾式左转车道的主要因素,并结合国内外研究,从左转车道的长度和宽度等方面对左转车道的设计进行探讨,提出平面交叉口港湾式左转车道的安全设计方法并分析其安全效益。     

基于系统工程的春运摩托车返乡潮现象的交通事故机理分析

春运摩托车返乡潮是我国近几年出现的独特新现象,其交通事故频发的状况引起了社会的高度关注。针对此问题,采用交通系统工程的分析方法,构建了摩托车交通安全系统的基本要素及其相互关系模型图,以有关的文献报道和调查资料为基础,从人、车、路、环境和管理等方面归纳分析了恶劣天气型、疲劳行车型、黑夜行车型、路况不熟型、路况不良型及骑车技能不佳型等6种类型摩托车交通事故的机理。最后分别给公路管理部门、交警部门及政府提出了对策建议。     

基于交通冲突技术的行人安全分析与改善

从研究行人安全的角度出发,简要介绍了行人交通冲突技术及冲突成因,通过实例调查分析,探讨了交叉口信号配时对行人安全的影响以及闯红灯人数与行人冲突的关系,建立了行人绿信比与闯红灯比例、行人绿灯时转弯车与行人冲突数的关系模型,分析了行人冲突特性,用一种潜在事故指标表征行人安全.最后,针对存在的问题提出了相应的行人安全改善措施,并对3种冲突改善措施的效果进行了对比,得出相关结论.     

山区公路灾后重建施工质量及安全保障措施

针对甘肃省陇南地区山区农村公路发生地震灾害后的地质特点和存在的安全隐患,以省道S205线公路恢复重建工程建设为例,结合工程实际情况和特点,介绍了山区农村公路地震后恢复重建工程中,路面施工质量及安全保障措施等方面取得的主要成果和经验     

基于FLAC~(2D)的膨胀土边坡稳定性影响因素分析

膨胀土滑坡问题在工程建设领域出现的越来越多,准确地了解膨胀土土体各项参数对其稳定性有何影响显得尤为重要。以宿州至扬州高速公路天长段膨胀土边坡实例为计算模型,利用正交试验探讨了边坡土体天然密度、粘聚力、内摩擦角、弹性模量和泊松比对其稳定性的影响,得出了一些有意义的结论,为工程建设中膨胀土边坡设计和治理提供参考。     

Structural safety of trams in case of misguidance in a switch

Tram vehicles mainly operate on street tracks where sometimes misguidance in switches occurs due to unfavourable conditions. Generally, in this situation, the first running gear of the vehicle follows the bend track while the next running gears continue straight ahead. This leads to a constraint that can only be solved if the vehicle's articulation is damaged or the wheel derails. The last-mentioned situation is less critical in terms of safety and costs. Five different tram types, one of them high floor, the rest low floor, were examined analytically. Numerical simulation was used to determine which wheel would be the first to derail and what level of force is needed in the articulation area between two carbodies to make a tram derail. It was shown that with pure analytical simulation, only an idea of which tram type behaves better or worse in such a situation can be gained, while a three-dimensional computational simulation gives more realistic values for the forces that arise. Three of the four low-floor tram types need much higher articulation forces to make a wheel derail in a switch misguidance situation. One particular three-car type with two single-axle running gears underneath the centre car must be designed to withstand nearly three times higher articulation forces than a conventional high-floor articulated tram. Tram designers must be aware of that and should design the carbody accordingly.     

Assessment of the influence of the elastic properties of rail vehicle suspensions on safety,ride quality and track fatigue

A sensitivity analysis has been performed to assess the influence of the elastic properties of railway vehicle suspensions on the vehicle dynamic behaviour. To do this, 144 dynamic simulations were performed modifying, one at a time, the stiffness and damping coefficients, of the primary and secondary suspensions. Three values were assigned to each parameter, corresponding to the percentiles 10, 50 and 90 of a data set stored in a database of railway vehicles. After processing the results of these simulations, the analysed parameters were sorted by increasing influence. It was also found which of these parameters could be estimated with a lesser degree of accuracy in future simulations without appreciably affecting the simulation results. In general terms, it was concluded that the highest influences were found for the longitudinal stiffness and the lateral stiffness of the primary suspension, and the lowest influences for the vertical stiffness and the vertical damping of the primary suspension, with the parameters of the secondary suspension showing intermediate influences between them.     

A yaw-moment control method based on a vehicle's lateral jerk information

Previously, a new control concept called ‘G-vectoring control (GVC)’ to improve vehicle agility and stability was developed. GVC is an automatic longitudinal acceleration control method that responds to vehicle lateral jerk caused by the driver's steering manoeuvres. In this paper, a new yaw-moment control method, which generates a stabilising moment during the GVC command and has positive acceleration value and the driver's accelerator pedal input is zero, was proposed. A new hybrid control, which comprises GVC, electric stability control and this new control, was constructed, and it was installed in a test vehicle and tested on a snowy surface. The very high potential for improvement in both agility and stability was confirmed.