A Review of the Key Points in the Design of Small-Radius Curved Ramp Bridges

This article explores the fundamentals of small-radius curved ramp bridges.It covers the selection of box girder spans,support methods,and forms,along with design optimization techniques for this type of bridge structure.The purpose of this paper is to provide robust support for enhancing the design quality of these bridges and ensuring their efficacy in real-world applications.

Study of the seismic performance of expansion double spherical seismic isolation bearings for continuous girder bridges

The development of an expansion double spherical seismic isolation (DSSI) bearing by modifying the fixed DSSI bearing is described in this paper. The expansion DSSI bearing is characterized by its good energy dissipation and horizontal displacement capacity and has been successfully integrated into the seismic design of several important engineering projects in China. It is envisioned to be used as a substitute for ordinary expansion bearings in continuous girder bridges to distribute the longitudinal earthquake action among all the piers. Its development, configuration and working mechanism are introduced first. The test method and the seismic performance of an expansion DSSI bearing are then briefly described. A theoretical analysis followed by a numerical analysis for an actual four-span continuous girder bridge are provided as an example, and it is concluded that the expansion DSSI bearing can be integrated into the seismic design of continuous girder bridges.

Simplified Method and Influence Factors of Vibration Characteristics of Isolated Curved Girder Bridge

The isolated curved girder bridge's vibration characteristics play a major part in the seismic responses of structures and anti-seismic properties.A clear analytic relationship between design parameters and the system's vibration characteristics could be established by its simplified dynamic analysis model,making it convenient for providing a reference to the optimization of design and safety analysis.A double-mass six-degree-of-freedom model for curved girder bridges with isolation bearings installed at the top of the bridge piers is built and a simplified analysis method for the vibration characteristics of the system is provided.Combined with the Matlab programming,the influences of radius of curvature,central angle,bridge deck width and damping ratio of the isolation layer and circular frequency of the isolation layer of isolated curved girder bridges on the pseudo-undamped natural circular frequency(called pseudo-frequency for short)and system damping ratio are systematically analyzed,and the sensitivity of vibration characteristics of isolated curved girder bridges is studied.The results show that the vibration characteristics of isolated curved girder bridges can be reflected well with this simplified model and calculation method.The pseudo-frequency of curved girder and system damping ratios increases with the increase of the isolation layer.The third-order vibration characteristic is more sensitive to the parameters of a curved girder,and the first-order vibration characteristic is sensitive to both central angle and radius of curvature to some extent while insensitive to the width of the bridge deck.Furthermore,the second-order vibration characteristic is not sensitive to the parameters of a curved girder.

Coupled Vibration of Long-Span Railway Curved Girder Bridges and Vehicles

The structure of a long curved girder bridge is represented with a three-dimensional curved finite element model. Each 4-axle ~vehicle is modeled by a dynamic system of 35 degrees of freedom. The random irregularities of the track are generated from a power spectral density function under the given track condition. The dynamic interaction between the bridge and train is realized through the contact forces between the wheels and track. Then based on these models, the coupled equations of motion are solved by applying the time-integration and iteration techniques to the coupled system. The proposed formulation and the associated computer program are then applied to a real curved girder bridge. The dynamic responses of the bridge-vehicle system and the derailments and offload factors related to the riding and running safeties of vehicles are computed. The results show that the formulation presented in this paper can well predict dynamic behaviors of both bridge and train with reasonable computation efforts.

Preliminary Estimation of Torsion of Curved Bridges Subjected to Earthquake Loading

This paper focuses on the seismic response of the curved and post-tensioned concrete box girder bridges. More specifically, it investigates how the curvature influences the response of a bridge subjected to earthquake. Parametric analysis of different radius of curvature is performed and the internal forces, torsion moment, axial and shear along the bridge are calculated. Two types of connections are investigated, the monolithic connection and deck connection with bents and abutments with rubber bearing. The response spectrum seismic analysis was performed. The models were designed, according to the provisions of EC8-part 2, EC2 and the Greek regulations E39/99. Diagrams relating the curvature with the torsion moment have been obtained from the results of parametric analysis. These diagrams could be used by engineers for preliminary design of such kind of bridges.

Study on the Mechanical Properties of Irregular Curved Steel Box Girder for City Viaduct

This paper deeply analyses the influence of different local tectonic on stress performance of spatial curved steel box Girder Bridge, using the finite element analysis software to establish space finite element model of this bridge, calculation and analysis were made on the bridge of the strength, stiffness. It has certain reference value for guiding engineering design, have a good foundation for the mechanical properties and stability of linear and nonlinear further study of curved steel box girder.

The Layout and Simulation of Logarithmic Spiral Double Curved Arch Dam Transverse Joints

Because of its good condition with mechanics, logarithmic spiral double curve arch bam has been widely used in the practical engineering. The introduction of a new method in how to divide transverse joint in arch dam will be given and the further research of its calculation has been done. The C＋＋ is used in electronic procedure and the 3D simulation has been finished with AutoCAD, which will provide the object model for computer simulation of the arch dam and the division of finite element mesh. Meanwhile, this method in dividing the transverse joint in arch dam also can be taken as the calculated basis for the design and calculation of arch dam, construction lofting and the calculation of the work amount.

大跨度公铁双层斜拉桥主梁涡激共振机理与控制

以拟建的某主跨808 m公铁双层斜拉桥为工程依托,采用节段模型风洞试验研究不同攻角下双层桁架梁断面的涡振性能及5种气动控制措施的抑振效果,结合计算流体动力学(CFD)静态绕流模拟,对比分析双层桁架梁断面的涡振机理及控制方法.研究表明:主梁断面原设计方案在+3°和0°风攻角下存在明显的竖向和扭转涡振现象,且振幅超过规范允许值;间隔封闭上层桥面栏杆或增设抑流板可有效抑制主梁扭转涡振,但竖向涡振振幅仍不满足规范要求;上弦杆外侧增设风嘴可有效抑制主梁竖向和扭转涡振,而下弦杆外侧增设风嘴对主梁涡振抑振效果有限.气流经主梁原设计断面上层桥面分离后,在其上下表面形成周期性脱落的大尺度旋涡,并在上层桥面后部再附,这是主梁发生竖向涡振的主要诱因;上弦杆外侧增设风嘴可引导气流平稳通过上层桥面,消除了周期性的旋涡脱落,并在其上表面形成一段狭长“回流区”,从而有效抑制了涡振的发生.

古金赤水河大桥主桥总体设计

古金赤水河大桥主桥为(83.5+173.5+575+173.5+83.5)m半飘浮体系双塔双索面斜拉桥。主梁采用双边主梁断面钢-混组合梁,由工字钢主梁和混凝土桥面板组成,全宽43.8 m,设置裙板抑制主梁涡振。桥塔为下塔柱内收的A形塔,南、北塔塔高分别为217 m和261 m。由于山区超高桥塔塔墩景观效果欠佳,采用超高塔柱无塔墩方案,桥塔采用嵌岩群桩基础;针对山区桥梁养护不便的情况,索塔锚固采用耐候钢钢锚梁;针对剪力钉在拉拔力作用下承载能力降低问题,采用以开孔板连接件为主的钢-混结合构造实现锚梁牛腿壁板与塔壁连接。斜拉索采用公称直径15.20 mm、标准抗拉强度1860 MPa的钢绞线拉索,全桥共4×23对(184根),空间双索面扇形布置。由于斜拉索锚拉板+外置减振阻尼器景观效果不佳,选用全内置减振阻尼器方案。

深江铁路洪奇沥公铁大桥主桥设计关键技术

研究目的:洪奇沥公铁大桥是深江铁路的控制性工程,主桥采用主跨808 m公铁合建斜拉桥一跨跨越洪奇沥水道,上层布置8车道城市快速路,下层布置4线铁路。结合建设条件、结构特点及使用性能,对主桥结构体系、主梁横断面及结构形式、索-塔锚固结构、施工方法等关键技术展开研究,确定技术合理可行和经济节约的设计方案。研究结论:(1)首创了短边跨叠合板-桁组合梁斜拉桥结构体系,主桥长度减少20%,节省工程投资;(2)首次在4线铁路公铁合建斜拉桥上采用倒梯形双主桁截面,桥面布置紧凑、受力明确;(3)提出的边跨主梁采用矩形钢管混凝土叠合板-桁组合结构,集结构受力和锚固压重于一体,施工便捷;(4)发明了“自平衡交叉锚固+齿块锚固”的索-塔混合锚固方式,技术经济性高;(5)钢主梁创新采用“纵向大节段+横向分块”施工方法,解决了超宽超高超重整节段钢桁梁运输受既有桥净空限制的难题;(6)本研究成果可为公铁合建桁梁斜拉桥设计提供参考或借鉴。

不同地震激励方向下隔震曲线梁桥易损性分析

为进一步评估隔震曲线梁桥在地震激励下的抗震性能,从地震易损性角度出发并兼顾考虑地震激励方向对其易损性的影响。利用APDL建立采用板式橡胶支座的隔震曲线梁桥有限元模型,从PEER中选取同一地震事件中的近断层地震动,按规范规定比例输入水平双向地震动进行非线性动力时程分析,结合地震响应与损伤指标计算得到各构件地震易损性曲线;考虑地震激励方向的变化,通过MATLAB编程绘制得到桥梁结构构件(桥墩与支座)以及整体系统的地震易损性曲面,分析探讨地震激励方向对隔震曲线梁桥易损性的影响。结果表明:不同极限状态下各桥墩切向损伤条件概率明显大于其径向,各支座的切向与径向易损性相差不大,但仍是各支座的切向易损性略大于径向易损性;桥梁各构件(桥墩与支座)切向易损性对地震激励方向均表现出很强依赖性,而径向易损性对其的依赖性相对较弱,且伴随损伤等级的提高,构件易损性对地震激励方向更加敏感;桥梁整体系统易损性对地震激励方向的变化不太敏感,且因各构件响应之间的相关性较高,其系统易损性更接近于易损性最大的构件——易损性下限;当进行隔震曲线梁桥抗震性能评估时,应考虑不同地震激励方向对其地震易损性的影响,从而使得易损性分析结果更加合理,能够更加真实地反映隔震曲线梁桥的实际损伤状态。

考虑变墩高效应的小半径曲线梁桥地震易损性研究

为分析墩高变化形式对小半径曲线梁桥地震易损性的影响,以某互通式立交匝道桥第2联为背景,设计渐变型、凹岛型、凸岛型3种墩高变化形式曲线梁桥进行地震易损性研究。在提出的压弯剪扭耦合作用破坏的基础上,采用集中铰-纤维模型的桥墩建模方法,通过SeismoStruct有限元软件建立3种墩高变化形式曲线梁桥模型;选取符合Ⅲ类场地特性的50条地震波,利用能力需求比法,以位移延性比为损伤指标,研究不同变墩高形式下桥墩与支座的地震易损性。结果表明:当小半径曲线梁桥采用3种墩高变化形式时,以弯曲受力为主的中、高墩在地震作用下发生完全破坏概率较低,以弯剪或剪切受力为主的矮墩在强震作用下发生完全破坏概率较大,变墩高曲线梁桥可以适当提高矮墩的抗震能力;凹岛型墩高变化形式会增加矮墩的损伤概率,在抗震设计中应避免选择该墩高变化形式或尽可能优化墩梁连接方式;墩高变化形式对于支座的易损性影响小于对桥墩的影响。

有轨电车小半径曲线梁桥减隔震措施对比研究

为适应交通路网发展需求,小半径曲线桥被广泛应用,其中有轨电车小半径曲线桥占据较高的比重。为确保地震区有轨电车的抗震安全,常采用减隔震装置以减小地震响应。然而,不同装置类型和布置方式对减隔震效果存在较大差异,因此有必要深入研究优化策略。本文以某典型有轨电车小半径曲线桥为工程背景,基于多个单一减震装置有机组合,依据边墩控制位移、中墩降低内力的组合减震理念,提出了一种新型的组合减隔震装置,并选择适宜参数的摩擦摆支座(FPS)、铅芯橡胶支座(LRB)和液体黏滞阻尼器(FVD)三种减隔震装置,通过动力非线性时程分析,探究了各装置关键参数对于曲线桥减震效果的影响,并对采用不同减隔震装置的有轨电车小半径曲线桥地震响应进行对比分析。研究发现:本文提出的组合减隔震方案能够明显弥补单一减隔震装置的不足,达到更好的减隔震效果,值得在同类桥梁中推广应用;FPS与LRB对墩底内力控制效果较好,但会在一定程度上放大结构的墩梁相对位移;FVD对墩梁相对位移的控制效果更好,但对墩底内力的控制效果比其他两种减隔震装置差。

武汉市江汉四桥拓宽工程主桥设计关键技术

武汉市江汉四桥拓宽工程主桥采用与旧桥外形一致、呈反对称布置的主跨232 m独塔混合梁斜拉桥,跨径布置为(232+70+40+20)m,采用刚构体系。主梁采用钢-混叠合梁与预应力混凝土梁组成的混合梁,钢-混结合面位于主跨距桥塔中心线9 m处,主跨采用双边工字形叠合梁,桥面宽23.5 m,标准梁高1.6 m;边跨采用预应力混凝土边主梁和箱形截面主梁,桥面宽23.5~27.0 m,标准梁高2.1 m。桥塔采用“A”形混凝土塔,塔高114.5 m,其下布置整体式承台,采用18根ϕ2.8 m的群桩基础。斜拉索按空间扇形双索面布置,共104根斜拉索,采用标准强度1770 MPa高强平行钢丝索,主跨梁端采用锚拉板锚固,边跨梁端设置槽口锚固,塔端采用锚固齿块锚固,主塔斜拉索锚固区纵、横桥向均配置有无粘结预应力钢棒。汉阳岸边墩采用T形钢筋混凝土板墩及钻孔桩基础;汉口岸边墩、辅助墩均采用钢筋混凝土独柱墩及钻孔桩基础。桥塔塔柱采用爬模施工;边跨主梁采用支架现浇施工,主跨主梁采用悬臂拼装施工。结构计算结果表明,大桥结构刚度及应力均满足要求。

赤壁长江公路大桥主桥4号桥塔墩结合梁墩顶节段施工技术

赤壁长江公路大桥主桥为(90+240+720+240+90)m钢-混结合梁斜拉桥,主梁分为121个节段,由双边箱截面钢主梁、横梁、小纵梁等组成,4号桥塔墩墩顶钢梁共3个节段,考虑枯水期施工边跨侧滩地外露,采用浮吊拼装+墩顶拖拉法施工。桥塔墩设置墩旁支架辅助钢梁架设,墩旁支架采用简易支架,设计为分离直立柱结构,避免了传统斜立柱支架体系结构复杂且受限于围堰尺寸的影响;墩旁支架设置钢梁拖拉系统及钢梁姿态调节装置,以实现钢梁的拼装、纵移和姿态调整。墩顶钢梁利用浮吊在中跨侧依次拼装单节段钢梁杆件后向边跨侧分次拖拉,墩顶钢梁全部就位后,采用竖向调节装置通过“顶落梁”工艺精调钢梁高程和横向调节装置对钢梁横向偏位进行纠偏,保证墩顶节段姿态满足设计要求。借助主梁永久结构简化塔区临时约束设计,抵抗风荷载、施工不平衡荷载和不平衡索力造成的钢梁平动和转动,确保主梁悬臂节段施工安全。

振动标线设置对连续梁桥的挠度冲击系数影响研究

为了研究振动标线设置对长大坡桥梁结构挠度冲击系数的影响,以30 m连续箱梁桥和五轴车辆为研究对象,基于实际振动标线结构形式进行不平顺度模拟,建立车桥耦合振动方程。借助ANSYS及APDL语言,采用直接积分法进行求解,得到了不同跨中位置挠度时程曲线和冲击系数,研究了振动标线数量、组间距和位置对连续梁桥不同跨中截面挠度冲击系数的影响。结果表明,设置振动标线后连续梁桥挠度冲击系数均大于规范值,且最大值为规范值的2.40倍;振动标线组数增加对下坡方向第一跨跨中位置挠度冲击系数影响不大,但对第二跨跨中挠度冲击系数有较大影响;随着振动标线组组间距增大,不同跨中截面挠度冲击系数变化规律不同;振动标线设置位置对不同跨中截面挠度冲击系数有一定影响;当振动标线组数为6时,首条振动标线宜选择距梁端距离4 m位置,振动标线组间距宜为4.5 m,当振动标线组数为4或5时,需根据不同跨径布置选择相应的振动标线设置形式。研究结论可为桥梁结构中振动标线的设置提供参考。

中低速磁浮圆曲线钢箱梁桥车致振动响应研究

随着圆曲线钢箱梁桥在城市交通中的应用愈发广泛,为探究其在中低速磁浮车辆运行作用下的振动响应特性,基于多体动力学和有限元方法建立车辆-轨道-钢箱梁刚柔耦合动力学模型,采用动态电磁阻尼力影响的二维磁轨关系,并考虑轨道关键部件的参振作用,分析圆曲线段钢箱梁的振动特性,探讨钢箱梁板厚、车辆速度及车体质量对钢箱梁振动响应的影响。结果表明:受曲率影响,钢箱梁在发生弯曲的同时亦会伴生扭转,产生弯扭耦合振动;钢箱梁的振动主要由10~20 Hz的钢箱梁整体弯曲振动、30~40 Hz的钢箱梁扭转振动以及50~70 Hz的轨道局部振动引起;计算得到的钢箱梁跨中横向及垂向最大挠度分别为1.26 mm、3.88 mm,均满足相关标准要求,钢箱梁具有足够的支撑刚度;各工况下的垂向加速度均未超过5.0 m/s^(2)的限值,且最高达到2.2 m/s^(2);在板厚10 mm以及超员载荷工况下,横向加速度大多超过1.4 m/s^(2)的限值,且最高达到4.0 m/s^(2);车辆速度的减小和车体质量的增加均会放大弯扭耦合作用影响,而板厚的增加则能够有效降低弯扭耦合作用影响,当板厚由10 mm增至40 mm时,一阶横弯及扭转频率对应振幅分别减小94.3%、98.7%。

衢州西站综合交通枢纽项目结构设计

杭衢高铁衢州西站综合交通枢纽及配套项目由综合交通枢纽、站前广场及匝道组成。为解决工程中大跨度拱形钢箱梁、单层网壳+钢网格筒柱、双曲面混凝土屋面以及钢箱梁弯桥等设计重难点问题,设计中对拱形钢箱梁、拉杆拱弧形屋面、钢箱梁弯桥进行结构分析,并对单层网壳+钢网格筒柱进行整体结构缩尺试验及整体结构有限元分析,同时对重要的圆管节点进行足尺试验和有限元分析。结果表明:拱形钢箱梁结构整体刚度好,设计合理;拉杆拱结构自平衡可有效减小基础推力和基础尺寸;单箱双室钢箱梁弯桥强度、刚度、抗倾覆验算均满足设计要求;单层网壳+网格筒柱整体结构在2.0倍标准组合荷载下仍能保持弹性受力状态;通过节点试验和节点有限元分析,验证了大跨度自由曲面钢结构圆管焊接节点的力学可靠性。

考虑双重非线性的大跨度钢桁梁拱桥稳定性能评估

为评估钢桁梁拱桥稳定性能,优化结构构造,以岐江河大桥为背景,建立考虑几何与材料非线性的钢桁梁拱桥弹塑性计算模型,考察矢跨比f/L、宽跨比W/L、初始线形偏差、钢材屈服强度对钢桁梁拱桥稳定性影响,探究横撑构造与数目、横梁与横撑抗弯刚度对结构稳定性的优化效果。分析结果表明:f/L介于0.20~0.25时,钢桁梁拱桥稳定性相对优越;保持桥梁跨度不变而增加宽度能提高结构稳定性,当W/L由1/8增加至1/4时,稳定系数提高1倍;初始线形偏差明显影响结构稳定性,当初始横向变形量控制在l/3 000~l/1 000时稳定系数下降5%,而当变形量>l/1 000时稳定系数下降18%;钢材屈服强度对结构稳定性影响较小,250~350MPa 5种强度下的稳定系数相差<7%;现有横撑中,双米撑稳定性最好,其次为米撑、X撑、双K撑、K撑;相同用钢量下,采用米撑构造比K撑构造性能更好;增加横撑数目或增加横梁、横撑抗弯刚度可提高钢桁梁拱桥稳定性。