城市轨道交通网络末班车衔接优化模型

城市轨道交通网络运营结束阶段,末班车在路网换乘站内能否实现合理地衔接,最能体现出以人为本的客运服务以及科学高效的运营秩序。根据城市轨道交通网络特点,提出了城市轨道交通网络末班车衔接编制的原则。从站间列车运行时间约束、线间列车换乘衔接、末班列车线间衔接目标等角度,研究了轨道交通网络末班车衔接优化量化方法,建立了网络末班列车衔接优化模型。以北京轨道交通城区1号线、2号线和5号线局部路网为实例,编制了网络末班列车的优化时刻表。算例结果表明,模型及其优化算法可行,对路网运输计划编制工作有较强的实用性。     

青岛至连云港铁路运输组织模式研究

研究目的:青连铁路是一条承担中长途旅客运输和港口集疏运功能的干线铁路,速度目标值为200km/h,其旅客运输组织模式既不同于传统的既有客货混跑模式,也有别于纯客运专线的运输组织模式。如何合理确定青连铁路的运输组织模式,是影响青连铁路经济效益和社会效益的关键。研究结论:从旅行时间节省、能力利用均衡和动车组购置费等方面,经比较分析各种运输组织模式的适应性后,确定青连铁路性质为是以客运为主的客货混跑铁路,旅客列车采用动车组与普速旅客列车相结合的运输组织模式。该模式充分发挥了青连铁路的线路能力,极大满足了不同的客流需求,也兼顾了部分货物列车。     

动车铝合金车体焊接接头非线性疲劳累积损伤模型

动车铝合金车体焊接接头疲劳寿命对加载顺序比较敏感,而传统的Miner法无法考虑载荷加载顺序。本文在损伤曲线法的基础上,提出非线性累积损伤模型的数学表达式及参数拟合算法,给出平均应力情况下使用此模型的扩展算式,并对铝合金焊接的对接接头、角接接头进行两级加载实验。实验结果证明:本文模型计算误差小于10%,比传统的Miner模型有更高的精确度,说明这一模型可用于铝合金焊接结构疲劳寿命计算。     

土石方调配问题双层规划模型及算法研究

研究目的:针对铁路土石方工程中较少考虑对生态环境影响的现状,研究如何构建合理的土石方调配问题模型,实现铁路土石方工程与生态环境的有效协调,减少对生态环境的影响的同时,从而实现土石方工程系统最优的目标。研究结论:根据土石方工程具体特点,系统地描述土石方调配问题,在此基础上兼顾政府监管部门与施工企业双方不同的利益目标,建立土石方调配问题双层规划模型。在双层规划模型中,上层模型为土石方工程系统最优模型,下层模型为土石方调配费用最低模型。计算结果表明:土石方调配问题双层规划模型在减少对保护生态环境影响同时,降低工程建设成本。     

苛求软件可靠性方法、技术与模型研究

从瀑布式程序设计的角度,综述了苛求系统软件生命周期各阶段的可靠性方法、技术和模型,包括需求形式化建模与验证、屏蔽设计错误的多版本软件容错、函数式程序设计以及可靠度评估模型等。总结比较各自适用的开发阶段、面向的目标错误类型及优缺点。     

考虑支路路段双向车流相互影响的单向交通组织优化

考虑支路路段双向车流相互影响的因素,从道路负荷与公平性的角度出发,优化单向交通组织方案。建立一主多从的双层规划模型,上层规划是多目标规划,以单行交通组织方案为决策,以路段饱和度超限量最小化降低道路负荷、以车辆绕行系数最小化提高公平性。下层规划是考虑支路路段双向车流相互影响的均衡交通分配(每个点对之间的最短路各自由1个下层规划确定,但所有下层规划确定的最短路可一次性求解)。双层规划可用模拟退火算法求解,求解效果明显优于支路路段通行能力等量划分为双向分道行驶的传统优化方法。     

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     

钢管混凝土拱桥在车辆荷载作用下的非线性动力响应分析

根据随动硬化理论和钢管混凝土组合材料恢复力模型 ,提出了复杂应力状态下钢管混凝土组合材料的弹塑性应力应变关系。采用非线性有限元法 ,对一钢管混凝土拱桥进行移动车辆荷载作用下车—桥体系的动力响应分析 ,并进一步研究钢管混凝土组合材料进入塑性后对体系振动的影响 ,取得了较满意的结果 ,为钢管混凝土拱桥动力性能评价提供参考。     

高桥墩之间几何非线性效应的相互干扰分析

提出了高桥墩之间几何非线性效应的相干分析计算模型。它适合于应用平面有限元法的计算程序求解。通过一个实例和应用逐次渐近法验证了该模型的精度，并从中得到一些有用的结论。     

Storage space allocation in container terminals

Container terminals are essential intermodal interfaces in the global transportation network. Efficient container handling at terminals is important in reducing transportation costs and keeping shipping schedules. In this paper, we study the storage space allocation problem in the storage yards of terminals. This problem is related to all the resources in terminal operations, including quay cranes, yard cranes, storage space, and internal trucks. We solve the problem using a rolling-horizon approach. For each planning horizon, the problem is decomposed into two levels and each level is formulated as a mathematical programming model. At the first level, the total number of containers to be placed in each storage block in each time period of the planning horizon is set to balance two types of workloads among blocks. The second level determines the number of containers associated with each vessel that constitutes the total number of containers in each block in each period, in order to minimize the total distance to transport the containers between their storage blocks and the vessel berthing locations. Numerical runs show that with short computation time the method significantly reduces the workload imbalance in the yard, avoiding possible bottlenecks in terminal operations.