型钢混凝土转换梁在城市轨道交通高架车站中的应用

城市轨道交通高架车站因受环境的制约和建筑设计的要求,常需采用转换梁结构。结合工程实例,介绍了型钢混凝土转换梁在某城市轨道交通高架车站中应用情况,对结构方案比选、构件截面设计、指导规程选择及施工措施等进行了论述,提出型钢混凝土转换梁能够提高高架车站复杂结构关键部位的受力性能,满足特殊的建筑功能和造型要求,可为类似工程提供参考。     

浅析大型铁路客运站交通规划理念

以重庆北站北场交通规划为例,分析和判断了铁路客流对象、车站客流组织、旅客立体换乘、车站功能布局和车站管理模式5个方面的发展趋势；提出了现代铁路客运站在综合交通枢纽、站前集散广场、机动车进出通道、交通设施布局、客流组织方面的规划设计理念.     

牌楼长江大桥“梁重转移”法施工钢箱梁临时锁定区域受力优化

牌楼长江大桥主桥为主跨730m的双塔混合梁斜拉桥,主跨扁平钢箱梁采用桥面吊机整体吊装、悬臂拼装法施工,施工中采用“梁重转移”技术将待拼装节段与已安装节段分2次进行临时锁定,并提出采用特制的压力调节装置调节该区域受力。为分析该装置对临时锁定区域的受力调节效果,采用ANSYS软件建立钢箱梁节段模型,模拟施工中临时锁定区域的压力调节过程,分析压力调节前、后临时锁定区域的受力及变形,并对实际应用效果进行对比分析。结果表明:压力调节装置对临时锁定区域的水平受力优化效果明显,对临时锁定区的相对高差影响不明显;该压力调节装置的实际应用效果较好。     

中心城区主干路改造的设计要点探讨

中心城区主干路一般建成时间较早,随着城市化进程的加快和社会经济的发展,现状市政交通、管线已不能满足沿线用户的需求;路面出现不同程度损坏,影响了行车的安全性和舒适性;沿线各类城市市政设施缺乏统一性和规范性,严重影响了道路交通和城市周边形象,制约了城市形象的提升和进一步发展.针对中心城区主干路改造的设计要点,从道路功能定位、纵断面控制、路面材料、轨道交通协调与管理、现有乔木的处理等方面进行阐述.     

Flexible long range planning using low cost information

Contemporary transport planning requires a flexible modelling approach which can be used to monitor the implementation of a long term plan checking regularly its short term performance with easily available data; the original model is periodically updated using low cost information and this allows the evaluation of the changes to the plan which may be required. Such an approach requires models suited to regular updating and to the use of data from different sources. Models to update trip matrices from traffic counts have been available for some time; however, the estimation and/or updating of other model stages with low cost data has escaped analytical treatment. The paper discusses this idea and formulates the updating problem for an example involving a joint destination/mode choice model under various assumptions about the nature of the available data. Analytical solutions are proposed as well as some general conclusions.requests for offprints     

新一代机车控制柜功能测试台

描述了一种用于电力机车电子柜和微机柜进行系统级功能测试的试验设备,对其功能、系统组成和软硬件设计特点进行了说明.该测试台已完成样机试验,在测试精度和响应速度方面有很大提升.     

A Numerical Model for Multiple Phase Transformations in Steels during Thermal Processes

IntroductionltiswellknownthatmetallmpicalstrUcforeofsteelsandheattransferarefullycouPled.PhasechangesdependontemPertheeevoluton,whereastemPertheeisinfluencedbycontrastsofmaterialcharacteristicsbetWeenphasesandlatenheateffects.AlotofworkhasbeenpefformedonthssubeCt,andclassicalmodelsarenowwidelyimPlementedintofiniteelementcomPutercodes[l][2][31[4][5][61.Thesemodelsaregenerallybasedonf.AVramityPekinetics[7][8]l9]Whnthephasechangeisgovernedbydiffusion,.TheKoistinen-Marburgerlaw[l0]fOrmfornsi…     

FUZZY RELIABILITY ANALYSIS OF STRUCTURE

ＩｎｔｒｏｄｕｃｔｉｏｎＵｎｃｅｒｔａｉｎｔｉｅｓａｎｄａｍｂｉｇｕｉｔｉｅｓｉｎｖｏｌｖｅｄｉｎｓｔｒｕｃ－ｔｕｒａｌｐｅｒｆｏｒｍａｎｃｅｈａｖｅｂｅｅｎｔｒｅａｔｅｄｗｉｔｈｔｈｅｕｓｅｏｆｐｒｏｂａｂｉｌｉｔｙｔｈｅｏｒｙ．Ｉｔｉｓ，ｈｏｗｅ...     

Mitigating the effect of impact loading on a vehicle using an essentially nonlinear absorber

The aim of this study is to investigate the ability of an essentially nonlinear vibration absorber to mitigate the large accelerations transmitted to a passenger compartment of a vehicle which is subjected to shock-type transient loading at the chassis. For such problems, the induced vibration typically attains its maximum value shortly after the application of the loading; thus, it may be impossible to dissipate a major portion of the input energy prior to the occurrence of the peak response. Here, a class of absorbers possessing a form of discontinuous essential stiffness nonlinearity is employed to achieve the desired mitigation. In this paper, we apply a single vibro-impact (VI) absorber to the chassis and examine whether the resulting energy transfer mechanism is an effective way to reduce the peak value of the inertial force measured at the passenger compartment. The influence of the absorber parameters is first studied based on a practical impulsive force, and the optimal design of the absorber is then obtained. Next, an asymmetric clearance arrangement of the absorber is suggested to facilitate the mitigation. Finally, an impulsive acceleration excitation is applied to the system to examine the robustness and efficacy of the optimised absorber. Results of numerical simulations demonstrate that a properly designed VI absorber can significantly decrease the maximum inertial force at the passenger compartment, generated by external impulsive excitations.