汽车用材料中多环芳烃限值与检测标准分析

多环芳烃是一类持久性有机污染物的总称,这类物质由于具有较高的脂溶性、强烈的致癌性以及难以自然降解的性质而被广泛关注。汽车产品的多环芳烃主要存在于非金属材料中。在汽车成为大众消费品的同时,人们越来越注重汽车使用中的环保与健康安全的问题。本文系统地对国内外汽车材料中多环芳烃限值要求及检测方法等相关标准进行梳理分析,形成对汽车行业禁限用物质多环芳烃的管控建议。     

环梁-桁架支撑体系在大型基坑工程中的应用

研究目的：北京西站地下行包库是北京西站改扩建工程中的一个重大项目,对整个工程的进度起着控制作用。通过本研究,拟找到一个施工便捷、结构合理的支护体系。研究方法：根据地质情况、周围环境要求、工程功能、当地的常用施工工艺设备以及经济技术条件综合考虑、因地制宜地选择支护结构的类型。采用理正单元计算、理正整体计算与SAP84计算相校核的计算方法,并对极限平衡法和弹性支点法的计算结果进行对比分析。研究结果：采用人工挖孔桩围护结构＋圆形环梁-桁架支撑的支护体系,其结构受力体系合理,便于施工,经济指标合理。研究结论：圆形环梁-桁架支撑的支护体系结构受力合理,适用于平面尺寸大、长宽尺寸接近、四周地层性质接近、抗力接近的基坑;混凝土圆形环梁结构受压合理,整体稳定性好;桁架体系整体性强,采用钢构件施工速度快;单撑式围护结构可以采用极限平衡法计算。     

压力管道工程水锤危害、防护措施及其研究计算方法

对水锤现象进行理论分析,并对其研究计算方法作简要概述。阐述水锤的起因、分类和造成的危害,并提出有效的防护措施。     

强震区板桩结构成层土地震土压力的计算方法

物部-冈部公式广泛应用于地震作用下的土压力计算,但因其适用条件的局限性,不能用于板桩墙后既含砂土又含有黏土的非均质土,且国内外规范对此类成层土的地震土压力计算没有统一的规定。总结国内外规范中成层土地震动土压力计算方法,找出其本质差异,在前人研究基础上引进整体极限平衡方法,结合SLOPE软件,得出强震区板桩结构成层土地震土压力的计算方法,并通过海外强震区港口工程实例验证,为同类工程提供参考。     

宜兴埠片区路网工程设计方案

通过对片区内组成路网的新建多条道路进行汽车保有量增长状况调查,运用四阶段法进行交通量预测和服务水平评价,得出规划路网中道路断面设置能够满足设计年限内交通量增长要求的结论,并经横断面设计方案比选,得出推荐方案横断面布置等设计成果。     

高速排水型船舶艉浪数值计算

采用近、远域结合的方法,对高速排水型船舶在深水状态下的NPL单体船、双体船以及三体船的艉浪进行数值计算,计算与试验比较表明该方法是可行性的,初步探讨了深水条件下单体船艉浪的衰减规律。     

舰船风浪航行失速的估算方法

将舰船常用的在风浪中失速的估算方法概括为7种,比较了各种方法的普适性、精确性和局限性,以便使用者选用.     

Approximate network loading and dual-time-scale dynamic user equilibrium

In this paper we present a dual-time-scale formulation of dynamic user equilibrium (DUE) with demand evolution. Our formulation belongs to the problem class that Pang and Stewart (2008) refer to as differential variational inequalities. It combines the within-day time scale for which route and departure time choices fluctuate in continuous time with the day-to-day time scale for which demand evolves in discrete time steps. Our formulation is consistent with the often told story that drivers adjust their travel demands at the end of every day based on their congestion experience during one or more previous days. We show that analysis of the within-day assignment model is tremendously simplified by expressing dynamic user equilibrium as a differential variational inequality. We also show there is a class of day-to-day demand growth models that allow the dual-time-scale formulation to be decomposed by time-stepping to yield a sequence of continuous time, single-day, dynamic user equilibrium problems. To solve the single-day DUE problems arising during time-stepping, it is necessary to repeatedly solve a dynamic network loading problem. We observe that the network loading phase of DUE computation generally constitutes a differential algebraic equation (DAE) system, and we show that the DAE system for network loading based on the link delay model (LDM) of Friesz et al. (1993) may be approximated by a system of ordinary differential equations (ODEs). That system of ODEs, as we demonstrate, may be efficiently solved using traditional numerical methods for such problems. To compute an actual dynamic user equilibrium, we introduce a continuous time fixed-point algorithm and prove its convergence for effective path delay operators that allow a limited type of nonmonotone path delay. We show that our DUE algorithm is compatible with network loading based on the LDM and the cell transmission model (CTM) due to Daganzo (1995). We provide a numerical example based on the much studied Sioux Falls network.     

Schedule-based transit assignment model with vehicle capacity and seat availability

In this paper, we propose a new schedule-based equilibrium transit assignment model that differentiates the discomfort level experienced by sitting and standing passengers. The notion of seat allocation has not been considered explicitly and analytically in previous schedule-based frameworks. The model assumes that passengers use strategies when traveling from their origin to their destination. When loading a vehicle, standing on-board passengers continuing to the next station have priority to get available seats and waiting passengers are loaded on a First-Come-First-Serve (FCFS) principle. The stimulus of a standing passenger to sit increases with his/her remaining journey length and time already spent on-board. When a vehicle is full, passengers unable to board must wait for the next vehicle to arrive. The equilibrium conditions can be stated as a variational inequality involving a vector-valued function of expected strategy costs. To find a solution, we adopt the method of successive averages (MSA) that generates strategies during each iteration by solving a dynamic program. Numerical results are also reported to show the effects of our model on the travel strategies and departure time choices of passengers.