Shake table experimental study of cable-stayed bridges with two different design strategies of H-shaped towers

As one of the main load-carrying components of cable-stayed bridges,bridge towers are typically required to remain elastic even when subjected to severe ground motions with a 2%-3%probability of exceedance in 50 years.To fulfill this special requirement imposed by current seismic design codes,reinforcement ratios in the bridge towers have to be kept significantly higher than if limited ductility behavior of the tower is allowed.In addition,since the foundation capacity is closely related to the moment and shear capacities of the bridge tower,a large increase in bridge construction cost for elastically designed cable-stayed bridge is inevitable.To further investigate the possibility of limited ductility bridge tower design strategies,a new 1/20-scale cable-stayed bridge model with H-shaped bridge towers designed according to strong strut-weak tower column design was tested.The shake table experimental results are compared with a previous strong tower column-weak strut designed full bridge model.A comparison of the results show that ductility design with plastic hinges located on tower columns,i.e.,strong strut-weak tower column design,is another effective seismic design strategy that results in only small residual displacement at the top of the tower column,even under very severe earthquake excitations.

Dynamic performance of cable-stayed bridge tower with multi-stage pendulum mass damper under wind excitations——I:Theory

In this paper, wind-induced vibration control of a single column tower of a cable-stayed bridge with a multi- stage pendulum mass damper （MSPMD） is investigated. Special attention is given to overcoming space limitations for installing the control device in the tower and the effect of varying natural frequency of the towers during construction. First, the finite element model of the bridge during its construction and the basic equation of motion of the MSPMD are introduced. The equation of motion of the bridge with the MSPMD under along-wind excitation is then established. Finally, a numerical simulation and parametric study are conducted to assess the effectiveness of the control system for reducing the wind-induced vibration of the bridge towers during construction. The numerical simulation results show that the MSPMD is practical and effective for reducing the along-wind response of the single column tower, can be installed in a small area of the tower, and complies with the time-variant characteristics of the bridge during its entire construction stage.

Dynamic performance of cable-stayed bridge tower with multi-stage pendulum mass damper under wind excitations—Ⅱ: Experiment

The possibility of using a multi-stage pendulum mass damper （MSPMD） to control wind-induced vibration of a single column tower of a cable-stayed bridge during construction was studied theoretically in part I of this work. In this paper, the performance of the MSPMD for reducing bridge tower vibration is studied experimentally. A MSPMD model and a tower model of the bridge with geometry scaling of 1：100 were designed and manufactured. Calibration of the MSPMD model with different wire lengths is conducted to verify the analytical model of the damper. A series of tests for the uncontrolled freestanding tower, tower with cables, and tower with MSPMD model are then performed under harmonic and white noise excitations. The experimental results show that the responses of the tower model significantly decrease with the installation of the MSPMD model, which demonstrates the effectiveness of the M SPMD to mitigate the vibration of the bridge tower.

General design of Sutong Bridge

The main span of Sutong Bridge is a double-pylon,double-plane cable-stayed bridge with steel box girder,which has the world's longest central span of 1 088 m within cable-stayed bridges.To overcome problems caused by severe meteorological conditions,perplexing hydrological conditions,deep buried bedrock and higher navigation level,many new technics and methods were created.Keys including structural system,steel box girder,stayed cable,tower,pier,tower foundation,collision avoidance system,wind-resistance,seismic-resistance,structural nonlinear response and structural static stability were presented individually in this paper.

六塔单索面矮塔斜拉桥拉索设计研究

六塔单索面矮塔斜拉桥是目前我国比较少见的斜拉桥。从斜拉索选型、斜拉索构造、斜拉索锚固和斜拉索减振等角度对六塔单索面矮塔斜拉桥的斜拉索进行了设计与研究。该桥采用抗拉强度标准值为1 860 MPa的钢绞线斜拉索,每根钢绞线的理论直径为15.2 mm。梁端斜拉索通过锚具锚固在预应力混凝土箱梁的隔板齿块上,而在塔端,采用索鞍分丝管形式将斜拉索锚固在桥塔锚固区。斜拉索在梁端采用粘性剪切型阻尼器进行减振,在塔端采用减振圈减振。为了提高斜拉索的使用寿命和耐久性,在钢绞线斜拉索外表面包裹环氧涂层、防腐油脂和高密度聚乙烯(HDPE)保护套。最后结合未知荷载系数法,对斜拉索索力进行了优化设计,优化后的部分索力虽略有增加,但主梁截面弯矩和应力更加趋于平稳,有利于结构受力。

Seismic design of high-rise towers for cable-stayed bridges under strong earthquakes

This paper presents the first of a series of studies on the seismic design of high-rise towers for cablestayed bridges under strong earthquakes.One practical cable-stayed bridge with a 730 m long main span and two high-rise towers over 200 m in height was selected for this study.The preliminary results show that compared with piers,the tower is more vulnerable to pulse-like earthquakes,and it may develop plasticity at certain locations.In addition,viscous dampers may not have the same effect during pulse-like earthquakes as they do under site-specific earthquakes.Hence,reoptimization of damper parameters or reconsideration of other energy dissipation devices will be needed if strong earthquakes are likely to occur.

预应力混凝土矮塔斜拉桥0号块钢束布置方案研究

成达万高速铁路渠江特大桥主桥为(139+278+139) m预应力混凝土矮塔斜拉桥,0号块为墩塔梁固结,固结区域构造及预应力钢束布置均较为复杂。为了探究该墩塔梁固结区域的应力分布,验证该区域预应力钢束布置的合理性及合规性,基于静力等效原理,首先提取出全桥整体计算模型的单元内力,并采用有限元软件建立0号块局部计算模型;其次将全桥整体计算模型单元内力转换至整体坐标系下并施加于有限元模型;最后对0号块在主力及主力+附加力等多种工况进行精细化计算分析,并对有无塔柱范围内竖向预应力钢束两种钢束布置方案分别进行计算分析和对比。计算结果表明,塔柱范围内布置竖向预应力钢束后,塔柱根部主拉应力由2.41 MPa降低至0.76 MPa,塔柱的应力分布状态也得到了明显的改善,同时也验证0号块纵向及横向预应力钢束设置的合理性,为该桥0号块位置纵横向及竖向预应力钢束布置提供了理论依据。

矮塔斜拉桥施工过程自动化监测系统设计与应用

为了减小施工过程对矮塔斜拉桥成桥状态的影响,以沙颍河大桥为工程背景,设计了矮塔斜拉桥施工过程自动化监测系统。该系统由数据采集子系统、数据传输子系统和综合监测云平台三部分组成,可实现应力、索力、主梁扰度、桥塔偏位等多种关键参数的连续自动化监测,并提供了监测预警功能。在自动化监测系统基础上,采用自适应控制法对案例工程施工过程中各关键参数进行监测调整,结果表明:索塔偏位误差均控制在5 mm以内,斜拉索索力误差均控制在±5%以内,主梁变形和应力所有一定误差,但均在可控范围之内,表明设计的自动化监测系统对于矮塔斜拉桥施工起到了较好的辅助作用。

高速铁路高低塔斜拉桥减隔震装置研究

通过分析各类减隔震装置对高速铁路高低塔混合梁斜拉桥的减隔震作用,从而选取合理减隔震装置。以阜淮(阜阳—淮北)新建高速铁路跨颍河主跨230 m的高低塔混合梁斜拉桥为研究对象,建立铅芯橡胶支座、摩擦摆式减隔震支座、黏滞阻尼器有限元模型,采用非线性时程分析法对塔底弯矩、梁端水平位移等目标函数进行地震响应分析。结果表明:采用铅芯橡胶支座,塔底弯矩降幅达到49.9%;采用摩擦摆减隔震支座,塔底弯矩降幅达到54.3%;采用黏滞阻尼器,塔底弯矩降幅达到62.0%。对于高速铁路高低塔混合梁斜拉桥而言,黏滞阻尼器减隔震装置更合理,并给出合适设计参数。

大跨度矮塔斜拉桥关键节点受力性能的仿真分析

宁波中兴大桥跨越甬江,其主桥由于机场航空限高的要求,采用主跨为400 m的大跨度矮塔斜拉桥设计方案。主桥采用V形钢主塔,塔梁固结并通过大型球钢支座支承在主墩上。经分析,索塔锚固区与塔梁固结处是主桥设计的2个关键节点。节点构造设计复杂,需借助3D空间有限元方法对其受力性能进行仿真分析。利用ANSYS软件建立关键节点的3D有限元仿真模型,并与MIDAS整体模型结果进行比较,验证仿真模型的有效性。通过仿真模型,得到不利荷载工况下关键节点空间应力分布的计算结果,为关键节点构造设计提供可靠依据。

温度效应对矮塔斜拉桥墩梁支撑体系的影响

为探究单索面多跨矮塔斜拉桥在温度作用下的受力特性,以某矮塔斜拉桥工程为例,基于Midas/civil软件建立了全桥有限元模型,分析了不同墩梁支撑体系下的多跨矮塔斜拉桥体系温度效应.分别考虑中塔、次边塔及边塔均为墩梁全固结(体系1),边塔为墩梁铰接、中塔及次边塔为墩梁固结(体系2),中塔为墩梁固结、次边塔及边塔为墩梁铰接(体系3),次边塔为墩梁固结、中塔及边塔为墩梁铰接(体系4),边塔为墩梁固结、中塔及次边塔为墩梁铰接(体系5)等5种组合下的墩梁支撑体系方案,分析墩梁支撑体系在升温或降温20℃时,主梁与主塔的应力与位移变化规律.研究表明,体系温度效应对墩梁全固结支撑体系下的主梁与主塔的位移与应力产生显著影响.在体系1中,体系温差为20℃时,主梁与主塔的最大位移分别为66.6 mm与94.07 mm,主梁与主塔应力分别为5.95 MPa与5.96 MPa;体系温度效应对仅在中塔处进行墩梁固结而其余位置进行墩梁铰接的体系下主梁与主塔的位移产生显著影响,但对其应力影响则较小;在体系3中,体系温差为20℃时,主梁与主塔的最大位移分别为74.20 mm与70.67 mm,主梁与主塔应力分别为0.59 MPa与0.48 MPa;在相同体系温度下中塔、次边塔和边塔位置任意选择两个墩梁固结,其余位置为墩梁铰接时,中塔、次边塔以及边塔位置处主梁结构响应显示出较高的相似性,且体系温度效应对主梁结构位移和应力产生的影响程度介于体系4和体系5之间.研究成果可为多跨矮塔斜拉主梁的施工线形控制提供参考.

多矮塔斜拉桥边跨现浇段无配重托架设计与施工

为研究多矮塔斜拉桥边跨现浇段无配重托架设计方法,并进一步完善与之匹配的施工流程,首先,依托西拉沐沦河特大桥边跨现浇段构造特征,提出无配重托架设计方法。其次,考虑无配重托架在边跨现浇施工过程中的外部荷载,通过有限元模拟,研究无配重托架受力性能,包括变形及材料强度冗余度情况,并明确了无配重托架局部构造的受力控制要点。最后,结合西拉沐沦河特大桥工程实践,总结完善了基于无配重托架的边跨现浇段施工流程,并明确了与无配重托架相关的施工注意要点。结果发现:所设计无配重托架在施工荷载下的最大变形为3.14mm,满足变形控制要求。无配重托架材料强度冗余度≥29.6%,安全储备良好;局部构造的材料强度冗余度≥65.5%,安全储备更高。西拉沐沦河特大桥工程应用效果显示,所设计无配重托架适用性良好。建议后续应用时,对箱梁中部对应的托架中间区域做进一步加劲处理。

矮塔斜拉桥施工关键技术与施工监控研究

矮塔斜拉桥是一种特殊类型的斜拉桥,其塔高度相对较低。矮塔斜拉桥采用较低的塔楼设计,以减少结构高度和施工难度,其施工过程相对于一般连续梁桥也更为复杂,需要进行合理的施工控制才能保证矮塔斜拉桥在复杂施工中的安全性、可靠性和经济性。以滁州大桥上部结构为背景,对桥梁施工中关键施工技术进行研究,确保其在桥梁上部结构和下部结构施工中的合理性。其次,对桥梁主梁及挂篮的位移和应力、拉索索力进行监控。研究结果表明:斜拉桥施工过程中,主梁挂篮位移和应力均满足设计和规范要求,拉索索力满足规范要求,实测索力值略小于理论值,全桥结构受力合理。

剑潭东江特大桥3号墩钢围堰施工关键技术

新建赣深高铁剑潭东江特大桥部分斜拉桥为主跨260 m的预应力混凝土四线高速铁路桥,3号墩采用24根φ3.0 m钻孔灌注桩基础,桩基均位于弱风化花岗岩层。针对大型船机设备无法进场,研究采用了现场整体拼装钢套箱围堰、气囊法滚动下水浮运及锚定卷扬机缆绳定位安装技术。通过采取结构优化、增设隔舱等措施保证钢套箱围堰下沉稳定。针对承台基底为弱风化花岗岩,应用钻孔桩柔性技术实现封底混凝土与桩基之间的柔性连接,钢围堰封底混凝土通过分舱封底保证质量。

在役矮塔斜拉桥主梁结构承载性能分析

矮塔斜拉桥具有纤细、优美的美学特征,同时可进行灵活的跨径布置,已成为中大跨径桥型的有力竞争者。对于在役矮塔斜拉桥,主梁承载特性是影响其结构安全的主要因素,开展桥梁主梁结构承载力研究对合理评价矮塔斜拉桥服役性能具有重要意义。为此,以某在役矮塔斜拉桥为例,基于桥梁检测结果,通过数值模拟方法建立了矮塔斜拉桥结构有限元模型,并从主梁抗弯、抗剪、抗裂角度研究了在役桥梁主梁结构的承载性能。期望研究成果能为类似桥梁的安全评价提供参考。

斜拉桥主塔环向预应力布设对主塔受力性能的影响研究

本文基于实体模型计算,探讨了不同环向预应力布束方案对斜拉桥塔锚固区混凝土应力状态的影响。经过对比分析,“井”字型布束因其施工方便、钢束应力利用率高和钢束用量小等优势被选为最优方案。此外,根据计算结果,本文提出了针对长边外侧钢束平面位置、锚固区之间竖向间距以及圆角半径的优化建议,旨在进一步提高预应力作用效果和减少防崩钢筋配束。

外倾式双索面PC矮塔斜拉桥颤振稳定性分析

基于浮山丞相河特大桥工程,对外倾式双索面PC矮塔斜拉桥主梁结构的颤振稳定性进行了分析。采用Midas Civil 2020有限元软件建立结构模型并分析结构动力特性,得到结构自振频率及振型,并分别对桥梁最大悬臂施工阶段和成桥阶段进行了颤振稳定性分析。通过新旧抗风规范对比分析,结果表明:该桥梁在2种工况下均具有较高的抗风稳定性,结构的颤振临界风速均远大于其颤振检验风速,结构安全,可供同类型桥梁在结构抗风设计时进行参考。

矮塔斜拉桥施工监控技术研究

文章以广州某矮塔斜拉桥为工程背景进行矮塔斜拉桥施工监控技术研究,系统介绍了矮塔斜拉桥的施工监控目的、方法、内容和具体实施过程。采用空间梁单元模型进行施工全过程仿真计算分析,对施工过程中结构安全进行评估。通过自适应控制法施工监控控制技术,最终得到的成桥状态与设计成桥状态吻合良好,各项指标均满足设计与相关规范的要求。所采用的技术方法可供同类型桥梁借鉴与参考。

矮塔斜拉桥塔梁墩固结粘接部位局部模型构建与应力分析

采用塔梁同步施工工艺可以在一定程度上缩短矮塔斜拉桥的施工工期,但也会给塔梁墩固结粘接部位局部应力形成较大影响。研究以我国兰合铁路某段矮塔斜拉桥为例,对该工程开展同步施工阶段矮塔斜拉桥塔梁墩固结粘接部位局部模型进行构建,分析了该工程局部应力分布规律,通过模型模拟分析结果与实际工程测试数据对比,对该模型的准确性进行验证。

多跨矮塔混凝土斜拉桥斜拉索安装工艺探讨

为研究多跨矮塔混凝土斜拉桥斜拉索安装工艺,以桥跨布置为(68+4×120+68)m的预应力混凝土梁五塔单索面矮塔斜拉桥——新津河特大桥为研究背景,对其斜拉索的安装流程及施工工艺进行了探讨,新津河特大桥斜拉索采用等值张拉法进行张拉,采用磁通量传感器并引入了钢绞线智能化数据采集系统对斜拉索索力进行监测,索力的控制取得了良好的效果。该桥斜拉索的顺利安装为同类型项目施工提供了参考。