Dynamic response of high-speed railway vehicle and welded turnout on large-span bridges based on rigid-flexible coupling system

Welded Turnout on Large-span Bridge(WTLB)is a complex multi-layer heterogeneous system and can significantly influence the service performance of High-Speed Railway(HSR).Understanding the coupling dynamic response of the vehicle and WTLB is essential.Previous research did not consider the dynamic behavior of foundations,leading to an underestimation of the vehicle-turnout-foundation coupling dynamic response,particularly when turnouts were laid on large-span bridges.This study proposes a novel modeling method that includes the foundations,to overcome the previous shortcomings by applying a rigid-flexible coupling system.In this approach,the vehicle was modeled as a rigid body sub-model in a Multi-Body Software(MBS),while WTLB was modeled as a flexible bodies sub-model using Finite Element(FE)software.The modal information from the FE model was imported into the MBS software.The two sub-models were coupled by the wheel-rail contact in the MBS environment and then the Vehicle-turnout-bridge Rigid-flexible Coupling Dynamic(VRCD)calculation model was established and it was discovered that the calculation results showed good agreement with the field test data.Through the VRCD model,the safety of the structure,the stability of the vehicle and the comfort of passengers were investigated,as well as several important infrastructure factors.The results demonstrate that this novel method provides accurate calculations and highlights the complex and significant interactions in the vehicle-turnout-bridge system.

Seismic Performances of Mountainous Continuous Rigid Frame Solid and Hollow Pier Railway Bridges

This paper focuses on the seismic performance of mountainous railway bridges having different pier type i.e. rectangular hollow piers and solid piers. The piers used were of same materials and inertial properties. For this, 3-D FEM models of these bridges were created by ANSYS 15.0. For seismic assessment, Response Spectrum and Dynamic Time-History Analysis methods were adopted. Different types of earthquake waves used were Elcentro, Wenchuan and Nepal earthquakes, all normalized to 0.3 g Peak Ground Acceleration (PGA). The study concluded that even though the hollow pier bridges are susceptible to large displacements, its dealing with internal forces is remarkable compared to solid pier bridges.

An analysis of the structural design of highway bridges in Mountainous Areas

Considering the characteristics of highway bridges in Mountainous Areas, The design principles of bridge structure design, such as structure form, superstructure, span and substructure, are described, the optimal design scheme of bridge structure is discussed from the aspects of safety, economy and so on in this paper.

Dynamic Reliability Assessment of Heavy Vehicle Crossing a Prototype Bridge Deck by Using Simulation Technology and Health Monitoring Data

Overloads of vehicle may cause damage to bridge structures,and how to assess the safety influence of heavy vehicles crossing the prototype bridge is one of the challenges.In this report,using a large amount of monitored data collected from the structural health monitoring system(SHMS)in service of the prototype bridge,of which the bridge type is large-span continuous rigid frame bridge,and adopting FEM simulation technique,we suggested a dynamic reliability assessment method in the report to assess the safety impact of heavy vehicles on the prototype bridge during operation.In the first place,by using the health monitored strain data,of which the selected monitored data time range is before the opening of traffic,the quasi dynamic reliability around the embedded sensor with no traffic load effects is obtained;then,with FEM technology,the FEM simulation model of one main span of the prototype bridge is built by using ANSYS software and then the dynamic reliability when the heavy vehicles crossing the prototype bridge corresponding to the middle-span web plate is comprehensively analyzed and discussed.At last,assuming that the main beam stress state change is in the stage of approximately linear elasticity under heavy vehicle loads impact,the authors got the impact level of heavy vehicles effects on the dynamic reliability of the prototype bridge.Based on a large number of field measured data,the dynamic reliability value calculated by our proposed methodology is more accurate.The method suggested in the paper can do good for not only the traffic management but also the damage analysis of bridges.

基于大涡模拟的山区桥址风场及其对桥梁抖振响应的影响

为研究位于复杂山区地形的桥址区风场特性及其对大跨度桥梁抖振响应的影响,以山区某斜拉桥为工程背景,采用大涡模拟方法获取桥址区足量监测点的脉动风场特性;分别以传统谐波合成法模拟的脉动风场、规范建议的C类脉动风场与大涡模拟方法计算得到的脉动风场计算桥梁的抖振力,并对三者进行了抖振响应对比分析;研究了桥址区非均匀风场特性对桥梁抖振响应的影响.研究结果表明:位于山区地形的大跨度桥梁的平均风速、风攻角以及紊流强度等特性沿桥跨呈现明显的非均匀性,紊流强度比、脉动风速谱以及相干函数均与规范建议值不同,反映了规范建议值在复杂山区风场中的适用性有限.采用谐波合成法模拟脉动风场得到的抖振响应相比大涡模拟方法同步监测所得到的脉动风场下抖振响应偏不安全,采用规范建议谱模拟风场所得的抖振响应相较于大涡模拟方法所得的抖振响应在竖向位移结果上偏不安全,但侧向位移和扭转位移结果上却偏于保守.非均匀风速对主梁竖向、侧向及扭转抖振响应影响较大,而非均匀风攻角对主梁扭转响应也有一定影响.非均匀风速来流下,跨中竖向和侧向抖振响应谱明显高于均匀风速来流的,而跨中扭转抖振响应谱与均匀风速来流相比差距并不明显.

瓮马铁路乌江特大桥设计关键技术研究

新建瓮马铁路乌江特大桥跨越两山之间深谷,地形复杂、设计难度大。为研究该桥梁方案,首先阐述了主桥的方案构思和结构设计,然后通过空间有限元软件对本桥进行静、动力仿真分析,总结了大跨铁路劲性骨架混凝土拱桥构造和受力特性。结果表明:主跨337 m上承式劲性骨架混凝土拱桥具有刚度大、徐变小、后期养护维修工作量小等优点,主拱圈采用小矢跨比设计,兼顾安全、经济、环保和美观,能够满足铁路桥梁跨越山区“V”形峡谷的要求;主拱圈由劲性钢管混凝土骨架外包C55无收缩混凝土构成,通过分层分段浇筑方案改善拱圈各构件的内力;拱上结合梁采用两片工字形钢与混凝土桥面板相结合的形式,钢梁栓焊结合,便于制造、运输和施工;拱座采用梯形断面扩大基础,基础开挖永临结合,有效降低施工风险;数值分析表明该桥结构的刚度、强度、稳定性均能满足规范要求,能够满足客货共线铁路的安全性和乘坐舒适性要求。可为其他山区铁路桥梁桥式研究提供参考。

山区铁路桥隧工程关键节材要素均衡优化

为在经济可承受范围内提升山区铁路的节材性能,提出了一种基于NSGA-Ⅱ的关键节材要素双目标均衡优化方法。首先,以断面超挖、喷射混凝土类型选择、围岩变形预留、桩基扩孔、桩头超封5个桥隧工程关键节材要素为决策变量,以CO_(2)减排量最大、建造成本增加值最小为优化目标,构建山区铁路桥隧工程关键节材要素均衡优化模型;其次,采用带精英策略的非支配排序遗传算法(NSGA-Ⅱ)求出Pareto均衡解集;再次,耦合主客观元素组合的综合赋权法与TOPSIS法对Pareto均衡解集进行科学决策,得到考虑决策者偏好的关键节材要素最佳组合,并分析决策者偏好对最佳组合的影响;最后,以某山区铁路工程某标段为例,系统地验证了该方法的科学性及适用性。研究结果表明:与优化前相比,最佳组合能实现CO_(2)减排12.622万t,对应建造成本增加了24.833万元,优化效率达到50.826%。

山区铁路桥梁与区域环境耦合协调测度及优化调控

山区铁路沿线地形复杂,桥梁占比高。为科学评估及优化山区铁路桥梁与区域环境协调状况,促进山区铁路桥梁与区域环境高质量协调发展,提出了一种山区铁路桥梁与区域环境耦合协调优化调控模型。在分析山区铁路桥梁与区域环境耦合作用的基础上,从设计视角构建山区铁路桥梁绿色设计要素及特征指标体系,并运用CRITIC法提取绿色设计关键要素;结合时间累积效应,以绿色设计关键要素为着手点,通过分析山区铁路桥梁可持续能力和环境承载水平,构建了山区铁路“桥梁-环境”复合系统耦合协调模型,对山区铁路桥梁与区域环境耦合协调程度进行测度,并以耦合协调指数最大化为目标函数建立反映“桥梁-环境”复合系统动态反馈机制的优化调控模型,运用粒子群优化算法求解,并提出了使山区铁路桥梁与区域环境向高质量协调发展的管控方案。优化结果表明,在保证“桥梁可持续能力≤环境承载水平”且获得偏离度最小的前提下,绿色设计关键要素优化比例分布于2%~40%,“桥梁-环境”耦合协调指数达到最大值622.4。该研究提高了桥梁与区域环境的协调发展水平,可为山区铁路桥梁与区域环境耦合协调状况评估及桥梁绿色设计提供新思路。

山区公路有限空间施工安全评价方法

山区交通工程建设经常面临狭窄地形条件下斜坡、弃渣、桥桩相互影响带来的安全挑战,需要综合评价由此产生的工程稳定问题。为了研究山区公路施工安全评价方法,依托某山区公路斜坡路段,在广泛调研狭窄地形路段工程建设特点的基础上,提出狭窄地形公路工程建设面临的共性安全问题,构建此类工程施工安全评价方法及控制标准体系,并在实际工程中应用、检验及完善该方法及指标体系。主要结果为:提出包括地基承载安全、改变地形边坡稳定性和结构安全的山区公路有限空间施工安全评价方法和安全控制标准体系。在山区公路有限空间工程建设中,需要控制弃渣填筑高度,控制加载造成的竖向应力小于承载力安全标准,实现地基承载安全;通过填筑体内部滑移、填筑体与斜坡地形接触面滑移、填筑体与自然地形深大滑移等潜在风险复核,实现边坡稳定性的全面控制;通过对桩基内力复核,控制堆载造成的结构内力小于结构承载安全标准。

山区钢桁梁斜拉桥设计和工程应用研究

随着交通强国和乡村振兴等国家战略的实施,我国山区桥梁建设的数量和规模与日俱增。文章调研世界范围内2113座山区桥梁(含中国1521座),分析山区桥梁的建设难点和应用现状,阐明山区斜拉桥的关键设计技术,研究山区钢桁梁斜拉桥主梁、主塔及斜拉索的方案选型及构造设计,探讨适用于山区条件的新型斜拉桥施工方法。结果表明:我国是世界上山区桥梁建设最多的国家,贵州省又居我国首位(34.4%)。山区斜拉桥通常具有大跨径、高塔墩、小边主跨比和结构不对称等特点,运输施工易、装配程度高、抗风性能好、抗震性能优和景观造型美的结构设计成为山区桥梁的主流趋势。钢桁梁比钢箱梁斜拉桥更适应于山区的建设条件,公路钢桁梁斜拉桥一般采用两片主桁,N形桁式,主桁高度为6~9m,节间长度为6~12m,梁上标准索距为12~16m。主桁横向联系采用华伦式,桥面系常用板桁组合体系,斜拉索则主要采用钢绞线斜拉索。新开发的缆索吊机法和节段纵移悬拼法解决了山区斜拉桥主梁整节段起吊、运输和拼装的难题,可供类似桥梁借鉴和参考。

复杂艰险山区高速铁路慢行病害特征与治理

针对我国西南复杂艰险山区高速铁路建设与运营中路基、桥梁和隧道出现导致列车运行速度减慢的病害(慢行病害),依托南昆、沪昆、西成高铁3条复杂艰险山区高速铁路运营期间监测与补充勘察资料,分析不同慢行病害的危害方式与变形破坏特征,研究高速铁路慢行病害产生的原因,提出治理方案。研究得出结论:地层岩性、地形地貌、构造应力环境、气候降雨、岩体结构条件等多重因素造成复杂艰险山区高速铁路出现路基基底上拱、斜坡桥梁位移、隧道基底上拱、隧道混凝土腐蚀等慢行病害,针对不同慢行病害提出多种治理方案。研究成果可为复杂艰险山区高速铁路工程建设、运营维护提供借鉴。

跨山区航道桥梁改建工程水沙条件影响研究

山区航道通航尺度小、比降大、流速快、枯丰变化明显、水文情况复杂。丽水莲都碧湖大桥改建工程位于瓯江干流中游,其所跨河段现状航道和规划航道线路不同,桥梁建设需同时满足现状航道通航和预留规划航道发展空间两项要求,因此对桥墩的布置提出了更高的要求。通过对桥梁通航净空尺度的计算分析表明,规划航道布置在主桥主跨内满足通航要求,而现状航道布置在主桥左侧桥跨内时,左侧主墩位于现状航道边缘,将对现状船舶通航安全构成影响。采用平面二维水流泥沙数学模型,研究桥梁改建对现状航道和规划航道水流条件和泥沙冲淤的影响,并提出将现状航道向左侧疏浚拓宽4 m,以满足通航要求的改善措施,可为跨山区航道的桥梁改建工程解决方案提供借鉴。

山区涉河桥梁墩柱冲磨破坏机理及防护措施

近年来自然灾害频发,山区桥梁水毁事故时有发生,针对山区涉河桥梁墩柱冲磨性能的提升正逐渐成为研究热点。该文综述山区涉河桥梁墩柱冲磨破坏机理及防护措施研究现状,并针对一种新型防护措施的防护效果进行数值模拟分析,以期为应对桥梁结构冲磨破坏问题提供参考。

地形复杂山区桥梁总体设计要点分析

针对山区桥梁地形起伏剧烈、地质灾害频发、建设材料机械运输困难、施工方法受限等问题,总分析了山区桥梁的设计特点,并从线位选择、桥型确定、上下部结构选型等方面进行了阐述,为山区桥梁设计提供系统性的方法和思路。

Seismic performance evaluation of large-span offshore cable-stayed bridges under non-uniform earthquake excitations including strain rate effect

This paper presents a novel and precise seismic performance evaluation method for large-span offshore cable-stayed(LSOCS)bridge by considering the strain rate effect of RC materials and the spatial variation effect of seafloor seismic motions. Threedimensional finite element(FE) model of a LSOCS bridge located in the southeast coast of China is constructed in the ABAQUS platform. The non-uniform ground motions at the offshore site beneath the bridge are stochastically simulated and used as seismic inputs. Moreover, a subroutine for considering the rate-dependent properties of RC materials in a fiber-based beamcolumn element model is developed to account for the strain rate effect of RC materials in the nonlinear time-history analysis.The numerical results indicate that seismic responses and fragilities of the LSOCS bridge are both considerably affected by the non-uniform seafloor seismic motions and strain rate effect. The seismic performance evaluation approach presented in this paper can provide vital support for earthquake resistant design of LSOCS bridges.

泥石流冲击下山区铁路车-轨-桥系统动力学行为特性研究

随着全球极端降雨事件愈发常见,复杂艰险山区泥石流灾害发生频次大幅增加,研究泥石流冲击作用下车-轨-桥系统动力学行为特性对保证桥上列车行车安全性具有重要意义。基于光滑粒子流体动力学(smoothed particle hydrodynamics,SPH)理论,建立泥石流冲击桥墩精细化模型,模拟泥石流冲击桥墩动态演化过程,获取泥石流冲击荷载,构建考虑泥石流冲击作用影响的车-轨-桥系统动力学模型,研究泥石流冲击桥墩作用下车辆和桥梁动力学响应变化趋势,探讨泥石流冲击强度和行车速度对桥上列车行车安全性的综合影响,明确桥上列车行车安全阈值。结果表明:SPH方法可以较好地模拟泥石流冲击桥墩动态过程,冲击过程中出现了明显的浆体爬高、回淤等现象;泥石流冲击作用引起桥梁在横向自振频率附近更剧烈的振动,可能加剧桥梁结构的损伤破坏;当泥石流荷载强度超过4.4 MN时,行车速度200 km/h列车的脱轨系数和轮重减载率均超出安全限值;当泥石流荷载强度超过6.2 MN时,行车速度160 km/h列车的轮重减载率超出安全限值,列车运行中可能面临脱轨的风险。研究成果旨在为泥石流灾害发生时桥上列车走行性能评估提供理论依据。

山地灾害环境下桥梁施工安全系统脆弱性评价

为确保山地灾害环境下桥梁施工安全,合理评价山地灾害环境下桥梁施工系统的脆弱性,结合脆弱性理论,以山区桥梁施工安全系统为研究对象,考虑山地灾害环境、桥梁施工特点及灾后影响,建立山地灾害环境下桥梁施工安全系统脆弱性综合评价指标体系。基于CRITIC的多属性决策组合赋权法,将应对能力和恢复能力作为基础变量构建脆弱性评价的二维云模型,结合MATLAB软件绘制综合云图与标准云图对比,可直观反映待评系统的脆弱状态,通过计算贴近度确定脆弱性等级。以天水市水家沟大桥为例,用该模型评价其施工安全系统脆弱性为“脆弱性中”Ⅲ级。通过现场调查,评价结果与实际施工情况相符,验证了该模型的有效性和合理性,为山区桥梁施工风险预防及控制提供参考。

山区高速铁路跨江河大桥方案研究

山区高速铁路地势起伏,选线控制因素多,铁路跨江河大桥需在已定线路大方向前提下结合桥位情况,采用地质、水文、孔跨条件最优的桥位。以南宁至深圳铁路容县北流河特大桥为例,研究分析了跨江河处孔跨选择思路与桥式设计方案的情况,通过研究得出,设计方案时应根据地面起伏、河流形态、通航条件、地质特点、工程预算等各方面全面比选确定,方能得到最经济合理的设计方案。

山地城市地下快速路方案设计研究--以烟台市塔山北路快速路为例

以烟台市塔山北路快速路工程为例,提出山地城市地下快速路的总体设计、交叉节点、防灾救援及智慧隧道方案.根据"两山夹一城"的地势条件,对穿城段方案进行了浅埋暗挖、叠层明挖和平铺明挖的综合比选,推荐平铺明挖方案,采用隧-桥-隧结合形式,实现"长隧短做",有效地降低了工程风险、难度和造价,以及机电系统的复杂程度和运维难度,为相似工程的方案和设计提供了可参考的经验.

跨河斜交桥梁对山区河流行洪影响试验研究

为探究斜交跨河桥梁对山区河流行洪的影响,以四川省某拟建斜交跨河特大桥为例,利用物理模型试验研究,分析了不同工况下桥梁建成前后的水流流态、流速与水位,桥梁建成后的冲刷深度,以及河势稳定性。结果表明:该类错孔布置的柱式墩斜交桥梁对河道水位、流速影响不大,对工程下游由右岸侧向左斜冲水流有一定阻碍作用,使得主流略向右岸侧有一定调整。桥梁所在河段仍属于河势稳定河段,拟建桥梁对河流行洪影响较小。