Determination of initial cable force of cantilever casting concrete arch bridge using stress balance and influence matrix methods

Cantilever casting concrete arch bridge using form traveller has a broad application prospect.However,it is difficult to obtain reasonable initial cable force in construction stage.In this study,stress balance and influence matrix methods were developed to determine the initial cable force of cantilever casting concrete arch bridge.The stress balance equation and influence matrix of arch rib critical section were established,and the buckle cable force range was determined by the allowable stress of arch rib critical section.Then a group of buckle cable forces were selected and substituted into the stress balance equation,and the reasonable initial buckle cable force was determined through iteration.Based on the principle of force balance,the initial anchor cable force was determined.In an engineering application example,it is shown that the stress balance and influence matrix methods for the determination of initial cable force are feasible and reliable.The initial cable forces of arch rib segments only need to be adjusted once in the corresponding construction process,which improves the working efficiency and reduces the construction risk.It is found that the methods have great advantages for determining initial cable force in cantilever casting construction process of concrete arch bridge.

The Forth Bridge's Human Cantilever:Engineering,Photography and Representation

During the Victorian Age,when the results of ambitious engineering radically transformed the principles of construction,photography proved to be a faithful and indispensable witness.This is plainly seen in the magnificent enterprise to build the railway bridge over the Forth River,accurately captured by the lens of the photographer and engineer Evelyn George Carey,whose excellent work to record those events is without equal.His almost daily annotations were free from symbolic meaning and monumental tendencies:it was the bridge itself that held the most important role.In the form of an experiment it was decided to illustrate the principle of the cantilever at the Royal Institution in 1887.It was during that particular circumstance that Carey produced the famous photographic image of the Human Cantilever.Carey presents to the observer an encyclopaedic array of representations and helps to truly visualise engineering.

Influence of concrete differential aging time on the construction phases analysis of the Fenghua River Bridge

The Fenghua River Bridge is a major structure on the highway between Hengzhang and Guojiachi, which is to be built with a four-span prestress concrete (PC) box girder and symmetrical cantilever castings. In this paper, a finite element method (FEM) model is set up to study the effects of concrete differential aging time on the construction phases of the Fenghua River Bridge by calculating the vertical displacement of the folding segment of the middle span and the longitudinal bending moment of Pier 12#. In the model, the girders are classified into 150 changing sections based on the desgn scheme, and their construction is to be carried in 16 phases respectively to build 12 blocks connected by a side folding segment and a middle folding segment, covered with a second dead load and in completion for 20 years. It is found that the internal forces and deformations of the concrete structures at the aging time of 60 d are quite different from those of 0 d aging time while the behaviors of the structures of 120 d aging time is nearly the same as those of 60 d aging time― the differences are so small that can be neglected, suggesting that the creep develops obviously about one month after the cement is hardened and the development fades later on.

Effect of concrete creep on pre-camber of continuous rigid-frame bridge

The effect of concrete creep on the pre-camber of a long-span pre-stressed concrete continuous rigid-frame bridge constructed by cantilever casting method was investigated.The difference of creep coefficients calculated with two Chinese codes was discussed.Based on the calculations,the pre-camber of a pre-stressed concrete continuous rigid-frame box bridge was computed for construction control purpose.The results show that the short-term creep coefficient and long-term creep coefficient calculated with the CC-1985 are larger than those calculated with the CC-2004,while the medium-term creep coefficient calculated with the CC-1985 is smaller than that calculated with the CC-2004.The difference of creep deformation calculated with these two codes is small,and the influences of concrete creep on the pre-camber for most of the segments are negligible.The deflections and stresses of the box girder measured during the construction stages agree very well with the predictions.

Research on the special lifting devices for steel box girders of Sutong Bridge

Sutong Bridge is a cable-stayed bridge with a steel box girder and a main span of 1 088 m.The steel box girder of main span includes five portions:back span large unit,large block of pylon,standard girder,back span closure girder and middle span closure girder.Each back span large unit is fabricated by welding several deck segments together in factory,and is erected by floating crane.As navigational clearance of the main bridge is high,the traditional truss lifting device can't satisfy the requirement of domestic lifting cranes for this kind of lifting height and weight.Hence,a kind of lighter lifting device for the erection of back span large units was accepted for this bridge.In this paper,the design and use of this lifting device is introduced.The upper structure used lifting gantry to install the standard girder segment by cantilever method.Because the bridge's navigation clearance is high,and the girder segment is wide and heavy,the meteorology and hydrology condition of the bridge district is abominable,and the requirements of long cable girder side pull-in,structure and performance propose high request to the lifting gantry.In this paper,the design and use key point of long cable pull-in angle adjustment device integrate into lifting gantry is introduced.

长阳天池口清江特大桥主拱圈悬臂浇筑斜拉扣挂系统设计

长阳天池口清江特大桥主桥为净跨径242 m的非对称上承式钢筋混凝土拱桥,主拱圈采用单箱单室截面,宽9.5 m、高4.0 m。资丘岸和五峰岸半跨主拱圈各分为24个和21个节段,第1个节段采用支架现浇,其余节段采用斜拉扣挂悬臂浇筑法施工。扣索采用星式和扇形组合方式布置,位于墩顶和扣塔的扣索为星式布置,位于交界墩墩身的扣索为扇形布置,并将墩身上的扣锚索设计成连续索以避免在墩身上搭设张拉平台;扣塔由8根∅800 mm×16 mm钢管组成,两岸扣塔分别高52.68 m和60.12 m;根据锚索最大索力,设计了能承受800 kN张拉力的岩锚索。建立主拱圈悬臂浇筑施工阶段MIDAS Civil有限元模型,对斜拉扣挂系统扣锚索索力进行计算,通过拆除部分扣索和调整扣锚索索力,施工期间主拱圈截面最大拉应力、扣塔最大偏位、主拱圈成拱后线形均满足要求。

武汉青山长江公路大桥宽幅钢箱梁悬臂拼装横向线形匹配技术

武汉青山长江公路大桥主桥为主跨938 m的双塔双索面全飘浮体系斜拉桥,主跨整体式钢箱梁高4.5 m、全宽48 m,采用500 t架梁吊机分节段悬臂拼装架设。钢箱梁悬臂拼装时,架梁吊机站位节段、待架节段由于荷载及约束不同,横截面变形呈现出不同的趋势,线形匹配难度大。为解决该问题,主跨钢箱梁悬臂拼装时选择上、下游分体式架梁吊机,减少架梁吊机自重;经比选选择横桥向27.7 m间距的架梁吊机站位,减小了架梁吊机荷载对横向线形匹配的影响;通过设置顶压装置(由顶压牛腿、支承底座组成),在架梁吊机站位节段、待架节段钢箱梁边腹板处施加1500 kN顶压力,配合少量马板,一次加载完成对接口竖向变形匹配调整。施工后,钢箱梁横向线形匹配精度均满足要求。

大跨径斜拉桥施工阶段临时抗风措施对比分析

研究目的:大跨径斜拉桥在最大双悬臂施工状态下结构刚度较小,对风荷载引起的结构风致振动响应较为敏感。本文以受沿海台风影响区域的一座主跨316 m斜拉桥为研究对象,根据风洞试验确定主梁的气动三分力系数,对比分析不同风缆布置方案与不同临时墩布置方式对大桥风致响应控制效果的影响。研究结论:(1)增设临时风缆可使主梁竖弯基频提高22.0%~32.5%,对结构自身的扭转基频影响效果不显著;临时风缆对主梁竖向位移和主塔顺桥向位移控制有一定作用,固定位置在主梁最大悬臂长度的80%~90%范围内效果较好;(2)临时墩的抗风减振效果显著优于临时风缆,临时墩的设置使主梁悬臂端竖向位移响应降低了53.5%~65.5%,对主梁悬臂根部的顺桥向弯矩与横桥向弯矩的控制效果较为明显,降幅11.7%~58.8%;(3)在选择桥梁临时抗风措施时,需综合考虑抗风需求、施工条件、施工风险和经济性;(4)本研究成果可为大跨度斜拉桥临时抗风措施的选择提供参考。

基于压弯破坏曲面的桥墩可靠性分析

非对称桥梁结构悬臂施工期间会对下部结构产生较大的不平衡弯矩,为分析钢筋混凝土(Reinforced Concrete,RC)墩柱在不平衡弯矩导致的双轴压弯下的可靠性,提出了基于压弯破坏曲面的可靠性分析方法。该方法使用倪克勤公式作为功能函数,并通过钢筋与混凝土本构关系求解倪克勤公式所需要的轴心受压承载力与单向偏压承载力,将RC墩柱的材料特性、几何特性、所受外部荷载作为随机变量,基于可靠指标物理意义,使用罚函数法将可靠指标求解问题转化为无约束最优化问题,利用遗传退火算法求解RC墩柱的可靠指标。采用该方法对文忠路上跨合肥东站改扩建工程主桥46号桥墩进行可靠性分析,结果表明:在悬臂施工至自重不平衡弯矩最大状态下,P1~P3支墩可靠指标分别为5.44、5.05、5.94;对可靠指标影响程度较大的随机变量依次为结构自重、钢筋强度和混凝土抗压强度,而风荷载对可靠指标影响相对较小。

大跨公铁两用钢桁拱桥边跨施工关键技术

常泰长江大桥天星洲专用航道桥为(168+388+168)m大跨重载公铁两用钢桁拱桥。主梁采用2片主桁双层板桁组合结构,边跨钢梁施工采用架梁吊机悬臂散件拼装。为确保边跨钢梁架设轴线和竖曲线线形,按照最快形成稳定桁片结构原则拼装,上墩前悬臂拼装并形成三角桁片稳定结构后再实施抄垫;在钢梁架设过程中对钢梁标高进行调整,精确控制钢梁上墩标高;为确保边跨钢梁架设结构受力满足要求,通过有限元理论分析比选,确定临时墩最优脱空时机;采用“基于空间六点调位法”对边跨钢梁进行整体精确定位;主墩支座采用重力法灌浆;基于多点变形协调,通过优化杆件安装工艺,解决了超静定结构杆件带力安装难题。

济阳黄河公铁两用特大桥施工关键技术

济阳黄河公铁两用特大桥主桥为(84+144+228+240+300+120+60)m非对称、多跨、不等高、矮塔钢桁梁斜拉桥,采用塔梁固结、塔墩分离的结构体系。主梁采用N形双主桁、双层桥面布置,上层通行6车道公路,下层通行双线铁路。主墩桩基利用黄河枯水期采用大型旋挖钻机成孔,位于黄河主河槽的主墩承台采用锁口钢管桩围堰成套施工技术,其余主墩采用钢板桩围堰施工。主墩承台大体积混凝土结构采用自动测温及内部循环冷却水控制的智能化温度控制系统,承台混凝土未出现有害裂纹。钢桁梁利用门吊吊装杆件,设置墩旁托架和临时墩,采用双悬臂拼装+单侧悬臂拼装方式架设,结合钢塔两侧跨度不对称及跨黄河险工河段、施工条件受限等特点,通过定点精确配重+移动配重+索力调整,确保了钢桁梁线形满足设计要求、架设过程安全稳定。钢塔利用组合起重设备和定位工装分节组拼,钢横梁利用塔顶吊架整体提升,保证了钢塔安装精度。

高速铁路大跨度钢桁架桥接触网腕臂安装技术研究

高速铁路大跨度钢桁架桥纵向伸缩量大且变位复杂,是影响接触网腕臂偏移等系统能否正常、安全运行的重要因素,如何解决接触网腕臂安装、偏移调整与钢梁伸缩之间的协同配合,目前国内在此方面鲜有研究。通过阐述受导线伸缩影响的腕臂偏移机理和大跨度钢桁架桥梁体纵向伸缩机理,分析在不同接触网锚段布置方式下大跨度钢桁架桥梁体伸缩对腕臂偏移的影响,并采用逐工点分析法总结不同工况下钢梁伸缩与导线伸缩对腕臂偏移影响的相互关系,揭示了接触网腕臂安装曲线在导线伸缩及钢梁伸缩共同作用下的计算方法。结合典型案例计算分析,建议采用不同钢梁跨度下的推荐锚段布置方式能有效降低腕臂偏移量,并提出应重点关注伸缩缝两侧锚段腕臂偏移问题、腕臂偏移为叠加关系时缩小半锚长度、钢梁跨度大于720 m时应重点计算伸缩缝两侧双腕臂间距等优化事项。研究内容及计算公式可为系统性解决高速铁路大跨度钢桁架桥接触网腕臂偏移设计、施工及运营维护等技术难题提供理论支持。

重庆白居寺长江大桥施工控制关键技术

重庆白居寺长江大桥主桥为主跨660 m的公轨两用双塔双索面钢桁梁斜拉桥。桥塔为空间曲线水滴形混凝土结构,采用爬模施工;钢桁梁为带边纵梁的倒梯形截面,利用桥面吊机进行对称悬臂施工。为确保成桥后的各项力学和线形指标满足设计要求,采用MIDAS Civil软件建立主桥施工阶段有限元模型,对塔顶偏位和应力、钢桁梁线形及斜拉索张拉进行施工监控。通过控制塔顶偏位以及关键断面应力,确保了钢桁梁施工中桥塔的安全;通过控制主桁和边纵梁的制造和安装线形,保证了钢桁梁成桥线形的控制精度;通过边、中跨1~5号索同步对称初张、6~20号索分级不对称初张及局部二次调索,提高了斜拉索的施工效率以及索力控制精度。施工监控结果表明:塔顶偏位最大偏差27 mm,钢桁梁线形最大偏差52 mm,斜拉索索力偏差在±5.6%内,均满足设计要求。

宜宾临港长江公铁大桥主桥超宽钢箱梁施工关键技术

宜宾临港长江公铁大桥主桥为主跨522 m的公铁同层双塔双索面钢箱梁斜拉桥,主桥钢箱梁宽63.9 m、高5 m,节段最大重量519.6 t。钢箱梁采用分部件加工、节段整体制作、场内预拼装方案制造。南岸钢箱梁采用边跨顶推+中跨单悬臂施工;北岸钢箱梁采用边跨存梁+双悬臂施工;中跨合龙段采用配切+顶推合龙。采用钢箱梁顶板与底板单元两拼工艺、钢箱梁锚固块体多工序组拼、预设反变形量的长线法总拼等制造技术,有效解决了超宽钢箱梁焊接变形量大的问题,大大提高了钢箱梁制造精度;南岸边跨钢箱梁利用中跨侧来梁进行顶推施工,解决了边跨运梁、吊梁施工难的问题,且避免了占用既有道路;北岸边跨钢箱梁利用枯水期预先存梁,解决了浅滩区钢箱梁施工受季节性水文影响大的问题,为双悬臂施工提供了先决条件;中跨合龙段采用现场配切+顶推施工,实现主跨钢箱梁精确合龙。

悬浇连续梁桥临时固结组合体系抗力计算

墩梁临时固结组合体系是悬浇连续梁施工过程中的主要受力构件,分析了该类墩梁临时固结组合体系的承载机理,提出了各部件对应的反力计算公式,采用ANSYS有限元软件建立缩尺计算模型,验证了公式正确性。在此基础上,对成都市新津县西新路桥梁的墩梁临时固结组合体系进行了施工验算,结果表明,此桥的墩梁临时固结组合体系安全、可靠;研究了各部件的参数取值变化对该类墩梁临时固结组合体系承载力的影响,结果表明,各组件的参数变化对此类墩梁临时固结组合体系的承载状态均有显著影响,其中体外钢支撑型号变化产生的影响最大,临时支座混凝土强度等级与临时支座高度变化的影响次之,体外钢支撑高度变化带来的影响最小。

大跨梁桁组合结构高铁斜拉桥主梁施工方案比选

西十高铁汉江特大桥主桥为(67+70+73+420+73+70+67) m斜拉桥,主梁采用预应力混凝土箱梁和加劲钢桁架组成的梁桁组合结构,钢桁架下节点与预应力混凝土箱梁采用PBL键连接。边跨及塔区混凝土主梁采用支架现浇施工,为选择合理的中跨混凝土主梁施工方案,提出5 m节段悬浇施工、10 m节段悬浇施工、5 m节段预制悬拼施工3种方案,从建设条件、结构受力、行车动力性能、桥面线形、施工工期和投资等方面对3种方案进行对比。结果表明:5 m节段预制悬拼施工方案的工期最短,但投资最高,且受建设场地和运输条件的制约;节段悬浇施工技术成熟,技术风险及质量风险低,相比5 m节段,10 m节段悬浇施工方案虽然投资略高,但能够有效节省工期达5个月,且结构受力性能、行车安全性及舒适性、桥面线形均满足相关要求,在保证施工监控精度的前提下,成桥线形也在可控范围内,该桥最终选择10 m节段悬浇施工中跨混凝土主梁。

加肋钢悬臂支撑-底部钢板组合桥面拓宽技术

[目的]在桥面拓宽施工过程中,常出现新旧桥连接处纵向开裂、拓宽桥面横向开裂等典型问题,如何通过优化和改进桥面拓宽技术解决这些问题是桥梁工程的一个重要内容.[方法]以国内首座跨海大桥——厦门大桥的桥面拓宽工程为背景,提出了一种加肋钢悬臂支撑-底部钢板组合的桥面拓宽方法.该方法有机结合了钢-混组合梁、正交异性钢悬臂板、底部加固钢板等桥面拓宽加固方法,采用混凝土现浇板作为桥面板、湿接法连接新旧桥梁,然后通过外延加肋钢悬臂构建支撑结构,并兼做现浇桥面混凝土的永久性模板.[结果]厦门大桥桥面拓宽加固工程的三维有限元仿真结果表明,钢悬臂布置间距增大会导致拓宽部分混凝土桥面板的拉应力增加,而设置下部加固钢板对于拓宽桥梁结构的挠度和应力分布影响明显.[结论]通过合理布置钢悬臂支撑结构和底部钢板,可显著减少拓宽部分混凝土纵横向裂缝的产生,改善拓宽后的桥梁的力学性能.相关成果有效支撑了厦门大桥的拓宽加固改造施工,为同类工程提供了有益的参考.

深中通道中山大桥主桥超宽大节段钢箱梁吊装匹配技术

深中通道中山大桥主桥为主跨580 m的双塔双索面钢箱梁斜拉桥,主梁采用流线型扁平钢箱梁,梁宽46 m(含风嘴),主梁共划分69个节段,标准段长18 m、最大吊重约429 t,采用桥面吊机双悬臂吊装。由于钢箱梁节段自重大、宽度较大、横桥向竖向刚度较小等,在桥面吊机悬臂吊装过程中,会出现钢箱梁匹配面高差过大(最大约63 mm)的问题。为解决该问题,实现梁段精确匹配安装,提出3种钢箱梁吊装匹配方案:“门架+拉索”方案、“牛腿反力架”方案、“一字梁锁定+C形焊缝+部分张拉斜拉索”方案。经有限元仿真分析综合比选,最终选择“一字梁锁定+C形焊缝+部分张拉斜拉索”方案。该方案以箱梁竖腹板为定位点,提前焊接一字梁,采用法兰连接后锁定待拼梁段,部分焊接拼接面内箱梁形成C形焊缝;通过提前挂索并张拉部分斜拉索,减小匹配面已拼梁段横桥向竖向变形,达到箱梁匹配要求。施工中采取了匹配高差调节、局部应力控制、拼接缝宽控制等关键技术,最终将该桥钢箱梁匹配面高差减小至9.8 mm以内,钢箱梁局部应力可控,斜拉索初张过程中钢箱梁应力增量小于10 MPa,且各箱梁节段拼接缝宽可控制在1 cm以内。

超低能耗建筑悬挑构件热桥隔断措施研究

相较于常规建筑,超低能耗建筑对围护系统的保温性能有着更严格的要求,其中,围护系统热桥控制是实现超低能耗建筑的关键措施。在围护系统保温构造设计时,由于悬挑构件隔断了保温层,成为热桥集中的部位,为削弱或消除此部位热桥,通常采用保温材料包覆悬挑构件的方式进行处理,但此方式存在工期影响严重及成本增量大的弊端,随着超低能耗建筑的推广,更多形式的热桥隔断措施在实际工程中得到了应用。结合常见的超低能耗建筑悬挑构件热桥隔断措施,从施工角度及隔热性能方面进行研究分析,以供同类工程借鉴。

平转施工桥梁转体角速度及角加速度合理取值分析

关于水平转体施工桥梁的转体角速度限值问题存在较大的争议,现有标准提出的0.01~0.02 rad/min的平转角速度限值偏于保守,造成部分转体桥无法在正常的铁路天窗时间内完成转体,而一些工程实际采用的转速大幅超过现有标准,但并未对结构安全造成任何影响。本文对转体角速度和角加速度与结构效应的对应关系进行理论分析,对国内相关研究成果进行归纳总结,并结合襄北编组站大桥的模型试验数据,按照转体悬臂长度提出转体角速度和角加速度合理取值范围。推荐取值为:悬臂长度不大于40 m时,角速度宜控制在0.05 rad/min以下;悬臂长度大于80 m时,角速度宜控制在0.025 rad/min以下;悬臂长度在40~80 m时,转体角速度的上限值可内插取值;转体角加速度宜控制在2.2×10^(-5)~4.2×10^(-5)rad/s^(2)。