Dynamic finite element model updating of prestressed concrete continuous box-girder bridge

The dynamic finite element model （FEM） of a prestressed concrete continuous box-girder bridge, called the Tongyang Canal Bridge, is built and updated based on the results of ambient vibration testing （AVT） using a real-coded accelerating genetic algorithm （RAGA）. The objective functions are defined based on natural frequency and modal assurance criterion （MAC） metrics to evaluate the updated FEM. Two objective functions are defined to fully account for the relative errors and standard deviations of the natural frequencies and MAC between the AVT results and the updated FEM predictions. The dynamically updated FEM of the bridge can better represent its structural dynamics and serve as a baseline in long-term health monitoring, condition assessment and damage identification over the service life of the bridge .

Improved methods for decreasing stresses of concrete slab of large-span through tied-arch composite bridge

Mechanical behavior of concrete slab of large-span through tied-arch composite bridge was investigated by finite element analysis (FEA). Improved methods to decrease concrete stresses were discussed based on comparisons of different deck schemes, construction sequences and measures, and ratios of reinforcement. The results show that the mechanical behavior of concrete slab gets worse with the increase of composite regions between steel beams and concrete slab. The deck scheme with the minimum composite region is recommended on condition that both strength and stiffness of the bridge meet design demands under service loads. Adopting in-situ-place construction method, concrete is suggested to be cast after removing the full-supported frameworks under the bridge. Thus, the axial tensile force of concrete slab caused by the first stage dead load is eliminated. Preloading the bridge before concrete casting and removing the load after the concrete reaching its design strength, the stresses of concrete slab caused by the second stage dead load and live load are further reduced or even eliminated. At last, with a high ratio of reinforcement more than 3%, the concrete stresses decrease obviously.

Degradation process assessment of prestressed concrete continuous bridges in life-cycle

To accurately evaluate the degradation process of prestressed concrete continuous bridges exposed to aggressive environments in life-cycle,a finite element-based approach with respect to the lifetime performance assessment of concrete bridges was proposed.The existing assessment methods were firstly introduced and compared.Some essential mechanics problems involved in the degradation process,such as the deterioration of materials properties,the reduction of sectional areas and the variation of overall structural performance caused by the first two problems,were investigated and solved.A computer program named CBDAS(Concrete Bridge Durability Analysis System) was written to perform the above-metioned approach.Finally,the degradation process of a prestressed concrete continuous bridge under chloride penetration was discussed.The results show that the concrete normal stress for serviceability limit state exceeds the threshold value after 60 a,but the various performance indicators at ultimate limit state are consistently in the allowable level during service life.Therefore,in the case of prestressed concrete bridges,the serviceability limit state is more possible to have durability problems in life-cycle;however,the performance indicators at ultimate limit state can satisfy the requirements.

Bridge Falsework in Staged Construction of a Prestressed Concrete Beam Bridge

The formwork and falsework in the construction of twin ribbed slab decks on a multi-span ecological bridge for a dual carriageway are presented. The bridge is situated in a valley plain which is crossed by small rivers and was designed principally with the environment in mind. The bridge length is over 356 m, and the width of the decks is 11.5 m. For the bridge works, a simple conventional falsework system was chosen with steel frames for the supports and steel rolled beams for the decks. The formwork was constructed in solid timber and plywood as multiple-use panels. The falsework was designed in order to build the two 10-span bridge decks in stages. The decks are continuous cast-in-situ prestressed concrete twin rib with spans of 30 m, 34 m and 45 m. An individual falsework system was designed, which was easy to move transversally following completion of each stage for one deck. After finishing each stage, for the second deck, the falsework was dismantled and used again in the next construction fronts. An individual arrangement for the falsework along with timber pilings was used to cross the biggest river. The formwork timber panels were used several times in the multistage bridge construction. The adopted falsework system is very simple, but it allowed the speedy construction of the two decks where there were severe time constraints.

预应力在我国大跨度结构中的应用研究综述

为了提高大跨度结构的正常使用性能,通常在混凝土结构中施加预应力.结果表明,预应力混凝土结构具有更好的使用性、耐久性和大跨度适用性,其中预应力混凝土空心板结构在不显著降低承载力和刚度的前提下明显减小结构自重,预应力型钢混凝土梁(板)结构采用较小的截面尺寸即可满足承载力和刚度的需求.开发城市地下空间是解决城市用地紧张的有效手段,我国地下大跨空间常用的结构形式主要包括密排框架(肋梁)结构、折板或拱形结构、变截面(加腋)板结构、预应力混凝土结构、型钢-混凝土组合结构和Y形柱结构6种形式,相比之下,跨度较大时宜采用预应力结构.

大跨径预应力混凝土连续梁桥加固研究进展

基于我国危旧桥改造需求多、病害情况复杂给桥梁加固提出的挑战,需把握桥梁加固国内外的研究现状,为未来深入研究和工程应用提供参考。结合大跨径预应力混凝土连续梁桥主要加固手段的基本原理,对各加固手段的优点、局限性及适用对象进行分析,系统梳理近两年来的最新研究成果,并对未来发展进行了展望。

某全民健身中心大跨度预应力钢筋混凝土跨层桁架结构分析与设计

为了实现某全民健身中心局部多层的无柱大空间,结构设计采用了在二层设置大跨度预应力梁和在三层、四层设置大跨度预应力钢筋混凝土跨层桁架的方案。采用SAP2000软件对比了跨层桁架中预应力筋一次性全部张拉施工和分层浇筑、分批张拉施工下杆件的内力情况,结果表明后者的桁架下弦杆件的最终拉力较小,符合设计要求。通过各施工阶段下桁架杆件的内力变化情况,确定了预应力筋的布置及数量。最后,介绍了本工程预应力杆件的设计和采取的针对性设计措施,说明了施工阶段的监测情况。通过以上分析及设计,验证了预应力钢筋混凝土跨层桁架结构的可行性,较好地实现了建筑功能。

深中通道泄洪区非通航孔桥主梁设计

深中通道泄洪区非通航孔桥总长6.05 km,分布于伶仃洋大桥及中山大桥2座通航孔桥两侧。泄洪区非通航孔桥采用等跨连续梁布置,4~6跨一联。主梁设计过程中,首先进行110、120、130 m三种跨径方案比选,确定采用最经济的110 m跨径方案。然后针对结构形式,提出预应力混凝土梁、钢-混组合梁和钢箱梁3种方案,从力学性能、经济性和施工风险等方面综合考虑,最终推荐采用钢箱梁方案。钢箱梁采用外形简洁流畅的封闭式断面,有利于后期维养;考虑全线景观效果,主梁高度取4 m,高跨比为1/27.5;横隔板间距取2.5 m,采用实腹式横隔板和框架式横肋的组合式设计,使箱室内部通透性更好;钢箱梁采用Q420qD钢和Q345qD钢2种材料。钢箱梁施工采用适合海上长大桥梁的大节段预制+现场拼装的施工方案。

基于荷载试验的预应力混凝土刚构桥承载能力评估

为了检测高墩大跨宽体箱梁刚构桥的桥梁承载能力及其动力特性,了解桥梁的健康状况,分析是否能满足设计及使用的要求。以凤凰特大桥为工程背景,建立有限元分析模型,通过静载试验和动载试验的结果与计算模型理论值进行对比和分析。在静载试验下,该桥的挠度校验系数为0.710~0.884,应变测点校验系数为0.603~0.800,相对残余应变和相对残余变位均小于20%。动载试验下桥梁左右两幅自振振动频率最小值为4.103 Hz,实测桥跨最大冲击系数为0.039。凤凰特大桥主桥左幅、右幅静载试验结论表明桥跨在正常使用状态下的承载能力能够满足公路-Ⅰ级汽车荷载的使用要求,动载试验结果表明,受检桥跨的实测自振特性及动力响应满足设计要求。

钢箱梁大节段整孔吊装线形控制技术

某跨海大桥部分连续钢箱梁采用大节段整孔吊装。钢箱梁大节段由小节段接长而成,在制造阶段考虑钢箱梁预拱度设置;为确保接长后钢箱梁制造误差满足要求,钢箱梁小节段出胎前进行预拼装,检查几何尺寸,并设置线形控制点;大节段组拼时通过线形控制点定位,并对焊接完成后的几何尺寸及线形进行复核。在架设阶段,建立大节段线形调整流程,将大节段调整到指定位置确定环切量;针对大节段架设存在梁端夹角的问题,利用墩顶千斤顶顶落大节段做刚体旋转调整其夹角,使得钢梁顺接。钢箱梁大节段安装成联后,高程和平面线形偏差总体均在10 mm以内,线形控制效果总体良好。

粮储建设项目预应力混凝土屋架安装施工技术

对于大跨度屋架而言,安装是其中最重要的工序,会对整个项目质量产生决定性影响。某粮储建设项目需要对预应力混凝土屋架进行吊装,在对工程基本情况进行概述的基础上,分析了屋架起吊前的准备工序,包括屋架吊装要求、屋架吊装前置流程、吊点设置以及钢丝绳选择、起重机性能确定等。从起模和吊装两个层面详细研究了屋架的安装施工技术,期间必须严格按设计施工要求执行,最后介绍了屋架的安装质量保障措施。

PC连续箱梁桥的日照温度效应及合龙温度研究

以云南省某大跨径预应力混凝土连续箱梁桥为工程背景,研究其日照温度效应以及合龙温度的确定。使用ANSYS数值模拟混凝土箱梁的温度场,结合实测值验证其可靠性,并拟合相应的指数型温度梯度曲线;使用Midas研究日照温度模式对混凝土箱梁桥施工中和成桥下的内力和位移影响;基于年温差效应对合理合龙温度进行研究,并针对非设计合龙温度下的合理施工提出相应的改善措施。结果表明,温度场计算理论得出的数据同实测值吻合较好;拟合出指数型的升温和降温模式下的温度效应公式,尤其是对最大悬臂状态的下挠影响显著,最大下挠值达21.6 mm;结构因整体升温或降温产生的横向位移值比竖向位移值大,升温22℃时,最大纵向位移值为-31.2 mm;合龙温度为10℃时,对主梁结构的受力最好,同时升温带来的结构上挠值对结构长期变形有利。

大跨连续刚构桥三向预应力筋滞后张拉研究

针对大跨预应力连续刚构桥具体施工过程中竖向、横向预应力筋的张拉存在随意性、不规范性的问题,以某特大桥为背景(68 m+120 m+68 m预应力混凝土连续刚构桥),利用MIDAS FEA有限元分析软件,建立2号到6号梁段的实体模型。通过使用生死单元技术实现对不同梁段、荷载、边界条件的激活,以达到模拟不同的施工阶段的目的,研究梁段沿着桥梁纵向的内力变化。经过多方面的对比后,结果表明,滞后一个节段张拉竖向、横向预应力筋可以让梁体的应力更为均匀,受力性能更为优异,因此推荐在施工过程中使用这种张拉工序。

大跨度预应力桥梁工程中挂篮悬臂浇筑施工技术

为解决大跨度预应力桥梁工程中存在悬臂预应力损失过多的问题,对大跨度预应力桥梁工程中挂篮悬臂浇筑施工技术进行研究。根据关门江水道大桥项目施工情况,分析大跨度桥梁工程中挂篮悬臂浇筑施工技术的具体应用,包括挂篮制作与安装、模板拼接、混凝土浇筑、悬臂桩预应力张拉等方面。对实际工程的支架位移进行检测,结果显示:测点处模板最大位移值为4.2 mm,混凝土浇筑完成二次收面处理,悬臂桩单桩预应力为5 000 kN。由此表明,模板连接紧密、混凝土浇筑均匀密实、预应力结果承提供受荷载效果良好,可有效解决悬臂预应力损失。

服役15年大跨跨海预应力混凝土梁桥荷载试验及结构性能评价

大跨预应力混凝土梁桥因其结构刚度大、行车平顺舒适、抗震性能好、施工技术成熟等优势得到广泛应用,该类桥梁在服役较长时间后,由于自然环境和超载的长期影响可能导致结构出现裂缝,并影响结构的安全承载能力,这一问题对于跨海桥梁显得尤为突出。因此,为准确评估在役跨海混凝土桥梁的实际工作状态与承载能力,通过对一座已服役15年的大跨跨海预应力混凝土梁桥进行现场静载、动载试验,并结合有限元对其振型等特性进行了分析。研究结果表明,桥梁结构的工作性能仍保持良好,但由于所处海域环境及长期服役导致的结构损伤和裂缝的影响,使其实际承载能力有所下降。研究成果可为在役同类桥梁的维修加固提供参考。

预应力混凝土梁桥关键施工技术分析

为保证预应力混凝土梁桥的施工质量,文章总结了连续梁桥的形式、受力特点等,分析了悬臂浇筑法的施工流程和特点。同时,以某公路连续箱梁桥为研究对象,从0#块支架计算和墩梁临时固结、挂篮预压、合龙等方面分析了施工要点,最后从线形控制和应力控制两方面阐述了连续梁桥的施工控制方法,研究成果可供类似桥梁结构施工借鉴。

高速铁路预应力混凝土连续梁桥施工BIM技术研究与应用

文章介绍了应用BIM技术开展高速铁路预应力混凝土连续梁桥施工的重要环节,分析了高速铁路预应力混凝土连续梁桥施工特点,在明确技术适用性的基础上,针对BIM模型建立、预应力筋碰撞检查、有限元仿真分析、施工过程监测管理等方面内容进行了强调,能够缓解以往设计与施工存在的衔接困难问题,提高施工过程监控水平。

桥梁工程大跨双塔钢混组合梁施工控制技术研究

以某地区的大跨度桥梁工程双塔钢混组合梁结构为例,结合该工程实际情况分析该工程的施工控制难点,并确定施工控制原则后,进行主塔线形控制、主梁应力控制、斜拉索索力控制、钢箱梁合龙控制。对控制效果进行测试后得出:梁顶高程最大控制误差为15.6mm,斜拉索的索力控制偏差结果均在5%以内,满足桥梁工程的施工标准规范。

三跨连续钢-混凝土组合箱梁桥力学特性分析

钢-混凝土组合结构桥具有自重轻、刚度大、延性高以及较好的结构整体性和稳定性等优点,已经广泛地应用于我国的桥梁工程中,但对于成桥后桥梁力学特性的研究较少。因此,依托福州前横路升级改造项目三跨连续钢-混凝土组合箱梁桥梁工程,通过荷载试验收集分析应变、挠度和桥梁模态数据。结果表明:荷载作用下各测点应变和挠度均小于理论值,沿横向分布与理论值趋势基本相同,实测腹板中性轴与理论中性轴基本一致,表明桥梁刚度较高、整体性较好;偏载作用下横向增大系数在1.107~1.254之间,桥梁抗扭刚度较大,不易发生倾覆;桥梁在环境激振作用下第1阶模态自振频率为3.430 Hz,大于理论值2.590 Hz,与理论模型相比具有更高的刚度。

大跨度连续刚构桥双柱墩系梁抗震影响因素分析

为研究大跨度连续刚构桥双柱墩的抗震性能和墩身系梁对桥梁抗震的影响,以青龙涧特大桥上跨陇海铁路立交涉铁工程大跨度连续刚构桥为背景,采用MIDAS有限元软件分别建立不同形式全桥有限元分析模型,进行E1、E2地震作用下的反应谱分析、时程分析和E2地震作用下桥墩延性抗震分析。结果表明:在E1地震作用下桥梁均未进入延性,各模型全桥完全处于弹性阶段,桥梁特征部位响应满足抗震需求,在E2地震作用下,墩底出现塑性铰区域,墩顶位移能力满足需求。对于长细比较大的桥墩,横系梁的设置会增大桥墩横向刚度并改善墩柱自身的弯矩分布,对桥梁抗震有利。在桥梁进入延性抗震阶段时,增设横系梁会减少墩顶位移,在满足延性抗震需求的情况下对桥梁稳定性有利。