新线开通对线网客流特征的影响

随着北京市轨道交通的快速发展,每年的新线开通都将对线网各线的客流分布产生较大的影响,但新线可研多注重新线自身的预测,缺乏线网整体变化的预测分析.结合线网客流变化的关键因素,探索利用新线可研和现有OD数据预测新线开通后线网客流的方法,并以北京地铁4号线开通为例进行验证,从一定程度上证明该方法的可行性和适用性.     

站内机车信号窜码掉码的原因分析及处理

工程设计施工考虑不周时,很容易造成设备开通后站内电码化出现机车信号掉码和窜码的现象。通过对站内机车信号掉码和窜码原因进行分析,找到工程设计施工时的缺陷和错误,并提出整改措施,消除行车安全隐患。     

新型列车运行控制系统——SCBTC系统

一种基于通行信号链的列车运行控制移动闭塞系统(SCBTC-MAS),可作为一个独立监测系统与现有列车运行控制系统(TBTC或CBTC)并联运行,为列车运行提供一个"双保险"机制。SCBTC-MAS具有精确、实时的轨道占用检测及闭塞控制能力,令列车在信号系统故障、列车定位失效、人为操作错误情况下,仍可有效避免相撞事故的发生。     

直线电机系统整体道床轨道施工技术

以广州地铁4号线和首都机场线引进的、国际领先水平的新型轨道结构（直线电机牵引系统）为研究对象,结合轨道工程施工实际,分析日本直线电机牵引和加拿大庞巴迪直线电机牵引城轨整体道床（尤其是道岔）铺设施工的技术特点,着重阐述首都机场线施工中的关键技术及解决方法。     

新建地铁隧道下穿既有地铁施工技术

北京地铁10号线国贸-双井站区间暗挖隧道施工下穿既有地铁1号线,既有线地铁结构的安全度已达临界状态,施工不能中断行车运营。为有效控制新线施工开挖引起的地层变化对既有结构位移和变形的影响,对既有线采用袖阀管注浆、WSS工法加固的措施,详细介绍新建10号线初支顶部与既有1号线初支仰拱零距离密贴、刚性支护紧贴1号线底板进行下部隧道施工的作业要点和技术措施,以确保施工安全和既有地铁的正常运营。实践证明,该工程首次采用密贴既有结构底板的形式穿越既有地铁隧道,对城市地下工程施工具有一定的指导意义。     

城市轨道交通轨道系统的设计优化和细化

轨道系统作为城市轨道交通的基本组成之一,基本理论和设计技术都比较成熟,本着精细化设计的理念,从施工的角度,将以往设计中一些有待进一步优化的问题加以总结,对轨道系统设计的优化和细化提出一些建议,供未来的新建工程设计参考.     

莫斯科地铁的特点及对我国地铁的启示

全面介绍莫斯科地铁在线网规模、车站设计、运营组织等方面的理念及特点,详细分析莫斯科地铁客流量大、运营效率高的原因,以期为我国未来地铁发展提供借鉴.     

现代有轨电车智能控制系统中的车辆定位技术方案

从现代有轨电车实际需求出发,参照沈阳市浑南新区现代有轨电车一期工程设计及建设经验,着重介绍现代有轨电车信号系统中的正线道岔控制系统、运营调度辅助系统等设计方案,可为后期国内及国际有轨电车信号系统设计提供借鉴。     

Surf-riding and oscillations of a ship in quartering waves

The behavior of a ship encountering large regular waves from astern at low frequency is the object of investigation, with a parallel study of surf-riding and periodic motion paterns. First, the theoretical analysis of surf-riding is extended from purely following to quartering seas. Steady-state continuation is used to identify all possible surf-riding states for one wavelength. Examination of stability indicates the existence of stable and unstable states and predicts a new type of oscillatory surf-riding. Global analysis is also applied to determine the areas of state space which lead to surf-riding for a given ship and wave conditions. In the case of overtaking waves, the large rudder-yaw-surge oscillations of the vessel are examined, showing the mechanism and conditions responsible for loss of controllability at certain vessel headings.List of symbols c wave celerity (m/s) - C(p) roll damping moment (Ntm) - g acceleration of gravity (m/s²) - GM metacentric height (m) - H wave height (m) - I _x ,I _z roll and yaw ship moments of inertia (kg m²) - k wave number (m^–1) - K _H ,K _W ,K _R hull reaction, wave, rudder, and propeller - K _p forces in the roll direction (Ntm) - m ship mass (kg) - n propeller rate of rotation (rpm) - N _H ,N _W ,N _R hull reaction, wave, rudder, and propeller - N _P moments in the yaw direction (Ntm) - p roll angular velocity (rad/s) - r rate-of-turn (rad/s) - R(,x) restoring moment (Ntm) - Res(u) ship resistance (Nt) - t time (s) - u surge velocity (m/s) - U vessel speed (m/s) - v sway velocity (m/s) - W ship weight (Nt) - x longitudinal position of the ship measured from the wave system (m) - x _G ,z _G longitudinal and vertical center of gravity (m) - x _S longitudinal position of a ship section (S), in the ship-fixed system (m) - X _H ,X _W ,X _R hull reaction, wave, rudder, and propeller - X _P forces in the surge direction (Nt) - y transverse position of the ship, measured from the wave system (m) - Y _H ,Y _W ,Y _R hull reaction, wave, rudder, and propeller - Y _p forces in the sway direction (Nt) - z _Y vertical position of the point of action of the lateral reaction force during turn (m) - z _W vertical position of the point of action of the lateral wave force (m) Greek symbols angle of drift (rad) - rudder angle (rad) - wavelength (m) - position of the ship in the earth-fixed system (m) - water density (kg/m³) - angle of heel (rad) - heading angle (rad) - _e frequency of encounter (rad/s) Hydrodynamic coefficients K roll added mass - N _v ,N _r yaw acceleration coefficients - N _v N _r N _rr N _rrv ,N _vvr yaw velocity coefficients K. Spyrou: Ship behavior in quartering waves - X _u surge acceleration coefficient - X _u X _vr surge velocity coefficients - Y _v ,Y _r sway acceleration coefficients - Y _v ,Y _r ,Y _vv ,Y _rr ,Y _vr sway velocity coefficients European Union-nominated Fellow of the Science and Technology Agency of Japan, Visiting Researcher, National Research Institute of Fisheries Engineering of Japan     

“低速动力性”说是EQ6100缸体疲劳的理论根源

追溯有EQ6100汽油机缸体疲劳的根源是偏颇的“低速动力性”说导致设计的疏漏。