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 .

Experimental research on mechanical properties of prestressed truss concrete composite beam encased with circular steel tube

Tests of 4 simply supported unbonded prestressed truss concrete composite beams encased with circular steel tube were carried out. It is found that the ratio of the stress increment of the unbonded tendon to that of the tensile steel tube is 0.252 during the using stage,and the average crack space of beams depends on the ratio of the sum of the bottom chord steel tube's outside diameter and the secondary bottom chord steel tube's section area to the effective tensile concrete area. The coefficient of uneven crack distribution is 1.68 and the formula for the calculation of crack width is established. Test results indicate that the ultimate stress increment of unbonded tendon in the beams decreases in linearity with the increase of the composite reinforcement index β0. The pure bending region of beams accords with the plane section assumption from loading to failure. The calculation formula of ultimate stress increment of the unbonded tendon and the method to calculate the bearing capacity of normal section of beams have been presented. Besides,the method to calculate the stiffness of this sort of beams is brought forward as well.

The Design and Analysis of Long-Span and Low-Depth Prestressed Composite Steel-Concrete Beam Bridge

The design scheme of long span and low depth composite steel concrete beams is introduced, and the methods of avoiding the cracking of concrete deck in the negative moment regions are proposed. Moreover, significant exploration for problems of the composite beams has been made, such as optimizing construction steps to regulate the stress, applying jacking technique to exert prestress on the concrete deck, investigating the uplifting force principle of the shear connectors by means of model test and non linear finite element analysis, and pointing out the countermeasure to reduce tension force of the shear connectors.

Test analysis on prestressed concrete composite beams with steel boxes subjected to torsion and combined flexure and torsion

While modem prestressed techniques have improved the torsion properties of high-strength concrete （HSC） composite beams with prestressed steel （PS） boxes, no research has been reported in either the national or international literature on the an- ti-torque and composite torque properties of this type of beam. With the aim of understanding the torque properties of these beams, this paper presents results of ten comprehensive tests; three of these were based on stirrup spacings and prestressing levels as the main parameters, while the other seven were based on torsional rates. The torsion tests were conducted on the re- sults which established several key parameters, including curves of constant torsion, strain curves of steel torsion, strain distri- bution of steel beams and concrete, curves of bending-moment and mid-span deflection, as well as cross strain distribution.The prestressing impact-factor method was adopted to deduce semiempirical equations for cracking torque in such composite beams. Furthermore, this involves the use of the equation of ultimate torque based on tress-model-theory of the distortion an- gle, the calculated results show good agreement with the measured values. In summary, this paper offers theoretical analysis for future applications of HSC composite beams with PS boxes, and provides both validation of the methods employed and a reference point for on-going research on composite beams and related anti-torque studies.

3D fracture modelling and limit state analysis of prestressed composite concrete pipes

In this manuscript,we study fracture of prestressed cylindrical concrete pipes.Such concrete pipes play a major role in tunneling and underground engineering.The structure is modelled fully in 3D using three-dimensional continuum elements for the concrete structure which beam elements are employed to model the reinforcement.This allows the method to capture important phenomena compared to a pure shell model of concrete.A continuous approach to fracture is chosen when concrete is subjected to compressive loading while a combined continuous-discrete fracture method is employed in tension.The model is validated through comparisons with experimental data.

预应力UHPC槽形节段与整体式混凝土板组合梁受剪性能

将预制的UHPC槽形节段通过干缝连接和预应力张拉形成槽形梁,再与整体现浇的混凝土板组合成的组合梁,称为预应力UHPC槽形节段与整体式混凝土板组合梁(PUCS-MCS组合梁)。它是一种能充分发挥不同材料的性能、施工方便且整体性能好的新型桥梁结构。为探究其抗剪性能,开展了9根模型梁的试验。分析了接缝数、接缝处剪力键数、剪跨比、UHPC钢纤维体积率、配箍率和纵筋率等参数对试件变形、破坏模式、抗剪承载力的影响;基于试验研究结果,提出了PUCS-MCS组合梁抗剪承载力计算方法。结果表明:PUCS-MCS组合梁均为剪压破坏,所有梁在开裂前的荷载-挠度曲线差异不大,在开裂后刚度不断下降;PUCS-MCS组合梁的抗剪承载力随接缝处剪力键数、UHPC钢纤维掺量、配箍率和纵筋率的增大而增大,随干接缝数量增加和剪跨比的增大而减小,其中影响最显著的是干接缝和剪力键,影响最小的是钢纤维掺量和配箍率,因此PUCS-MCS组合梁可不配箍筋,并可采用较低钢纤维掺量的UHPC。

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。

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。

大跨度铁路钢-混组合梁负弯矩区桥面板抗裂措施研究

为研究铁路荷载作用下大跨度钢-混组合梁负弯矩区桥面板开裂情况及抗裂技术,以某主跨168 m的铁路钢-混组合连续刚构桥为背景,采用MIDAS Civil软件对桥面板受力情况进行建模分析,并开展抗拔不抗剪连接件技术及预应力技术对桥面板抗裂性能影响的研究,结合抗裂措施工作原理及施工可行性,提出适用于减小负弯矩区桥面板裂缝宽度的实施方案。结果表明:采用普通栓钉连接、桥面板常规配筋条件下的钢-混组合梁,运营阶段主力及主力+附加力工况下负弯矩区桥面板裂缝宽度均不满足规范要求;墩顶处桥面板与0号块固结及非固结2种形式下,抗拔不抗剪连接件桥面板抗裂方案均不适用,抗拔不抗剪连接件的适应性受桥面板与0号块连接构造及桥面板整体与钢桁架上弦杆顶面连接形式影响较大;对桥面板配置纵向预应力筋能有效降低拉应力水平,设后浇带预应力筋张拉方案负弯矩区桥面板最大拉应力较桥面板浇筑成型后张拉预应力筋方案更低,更能充分发挥预应力效应,且便于工程实施,建议工程应用中宜控制湿接缝占比小于10%,预应力筋锚固断面拉应力突变值宜控制在2 MPa以内。

预应力波纹钢-混凝土组合板力学性能分析

为充分发挥波纹钢混凝土组合板力学性能,本文提出预应力波纹钢混凝土组合板结构。在利用试验结果验证数值模型准确性的基础上,对不同类型组合板进行了力学性能比较分析,研究了结构受荷历程和破坏模式,明确了上波纹钢板和预应力的作用机制,二者组合后显著提高了组合板弹性工作范围和抵抗破坏能力。进一步通过参数化分析,研究了预应力双层波纹钢混凝土(PSCS)组合板力学性能变化规律,结果表明:波纹钢板型号、核心混凝土厚度、栓钉间距及预应力水平对PSCS组合板抗滑移能力和抗破坏能力影响重大,其中核心混凝土厚度和波纹钢板波形影响更为明显,恰当的预应力水平能够更好发挥PSCS组合板力学特性。研究结果可为预应力波纹钢混凝土组合板结构的设计和优化提供参考和指导。

PK梁板在装配整体式框架结构中的应用

针对PK预应力混凝土叠合梁、预应力混凝土叠合梁同时在一个工程中应用遇到的模板设计与计算、起重设备的选型和吊具选择以及施工工艺等问题,结合工程实际情况,形成了PK预应力混凝土叠合梁板组合的施工工艺流程,确保PK预应力混凝土叠合板吊装的精确定位及受力性能,满足工程质量要求。

装配式GRC-PC复合墙板收缩性能的试验研究

文中开展了不同工艺条件下装配式GRC-PC复合墙板收缩性能的研究,并与单一材料墙板进行了对比。结果表明,GRC墙板与C30混凝土墙板的收缩应变随着时间的延长,呈现先快速降低后平稳的趋势;C30混凝土墙板的收缩应变稳定在-80×10^(-6)μm,较GRC墙板的收缩应变降低93.2%。与GRC墙板收缩应变相比,GRC-PC墙板的表面收缩应变及内部收缩应变的降低幅度分别为89.2%、94.9%;与C30墙板收缩应变相比,复合墙板内部的收缩应变降幅达到33.3%。加入钢丝网后,GRC-PC复合墙板+钢丝网的表面收缩应变开始下降,具有更好的抗裂性能。

预应力混凝土组合箱梁的抗弯性能试验分析

由于不同的加固方式会对预应力混凝土组合箱梁的承载力造成一定影响,使其容易出现弯曲变形,因此开展预应力混凝土组合箱梁的抗弯性能试验分析。以桩埕路改造项目为例,将四个25 m跨度的混凝土桥梁作为测试样本,使用三分点加载方式完成桥梁试件参数设计,布置测点时需在不同位置增加应变片,通过对有效拉应力与抗弯承载力的计算,将未加固的桥梁与使用板-混凝土组合方式加固的桥梁进行对比,分析其荷载-跨中挠度与抗弯强度对桥梁性能的影响。测试结果表明:所测试的桥梁试件跨中挠度在300~600 mm之间,荷载对应提升了1500 kN;极限状态下的承载力与加固之前相比,分别提升了54.38%、50.46%、55.22%;桥梁的抗弯强度和断裂伸长率相比没有加固的桥梁,桥梁试件A3分别增加了42.5 MPa和245%。对加固后的桥梁工程效果进行分析,未发现组合箱梁裂缝问题。

预应力混凝土钢管桁架叠合板生产工艺及质量管控

预应力混凝土钢管桁架叠合板作为一种预制板,近年来广泛应用于实际工程项目,但因其为预应力板,且板较薄,对生产工艺的质量要求极为严格,通过介绍该板的生产流程、各个生产环节质量管控措施,对预应力混凝土钢管桁架叠合板的生产及质量管控有一定的借鉴和参考意义。

跨线连续钢—混组合梁桥负弯矩区抗裂措施设计与研究

为改善跨线连续钢—混组合梁桥负弯矩区的受力性能以解决桥面板开裂问题,以深圳某高速改扩建工程4×85 m连续钢—混组合梁桥为研究对象。基于有限元法,研究增设预应力筋、支点升降法、后浇成型、微膨胀混凝土以及增大配筋率对负弯矩区桥面板抗裂性能的影响。结果表明:桥面板后浇成型可消除一期恒载引起的桥面板拉应力;支点升降法和预应力筋均能在桥面板中引入预压应力,有效降低桥面板的应力水平;增大配筋率只能减小最大裂缝宽度,当配筋率小于1.2%时,随着截面配筋率的增加,桥面板的最大裂缝宽度迅速减小,当配筋率超过2.4%时,随着截面配筋率的增加,桥面板的最大裂缝宽度减小幅度变小;微膨胀混凝土可有效减小桥面板的拉应力。最后基于工程实际提出了综合抗裂措施,可为后续类似工程设计提供参考。

小半径大跨度体外预应力钢混组合梁桥设计研究

通过介绍城区改造项目地理位置,拟定桥梁设计方案,阐述了狭小空间互通桥梁的设计理念。在跨路净空受限的条件下,钢混组合梁极大限度降低梁高。结合有限元计算分析,拟定钢梁和混凝土桥面板尺寸,并采用主梁箱体内施加体外预应力的方式,增加主梁抗弯、抗剪承载力及主梁刚度,从而改善小半径、大跨度跨路桥梁的受力状态,为类似交通改造工程的桥梁设计提供参考。

山区S形曲线桥梁施工关键技术研究

针对山区公路桥梁施工存在的机械材料运输困难、施工组织难度大等问题,本文旨在提出一套适用于山区S形曲线桥梁施工的预制T形组合梁制作、运输和安装方法,以提高施工效率和质量。首先分析山区桥梁施工的特点,对S形曲线桥梁中T形组合梁的预制流程及施工控制要点开展技术创新和优化。首先提出了改进的T梁预制方法,基于钢筋定位架优化了钢筋布设精度和效率,并通过智能张拉设备、自动喷淋系统等智能化手段,有效提高了预制梁的成品品质。其次,针对安装效率的挑战,研究提出了一种左右幅整体架设的预制梁安装方案,基于此对T形组合梁的安装流程进行了优化。通过在某大桥项目中的实际应用与验证,结果表明,本技术方案可提高T梁预制和架设精度,有效控制S形桥梁纵向及横向的线形。本研究为山区S形曲线桥梁施工提供了一套T形组合梁从生产到安装的全过程标准化技术方案,为类似项目提供了宝贵的技术参考与实践指导。

软土地区深基坑工程绿色支护技术的应用

我国碳达峰战略目标的确定,对基坑工程提出了更高的要求。文章以上海理工大学军工路516号校区某建设项目为背景,基于校园环境敏感、文明施工要求极高的特点,创新性地采用以预制、装配、可回收支护结构为主的绿色支护技术,包括型钢水泥土搅拌墙、预应力组合式型钢支撑、混合配筋预应力混凝土管桩等绿色工艺,减少了泥浆和废弃物排放,并采用矿渣、钢渣等工业废渣制成的高性能复合型土体硬化剂代替水泥进行土体加固。该项目的顺利实施对地下工程传统行业绿色转型,实现地下空间开发碳中和、碳达峰目标等有一定的借鉴意义。

预应力混凝土钢管桁架叠合板施工阶段性能分析研究

通过对3m跨、6m跨1.2m板宽预应力混凝土(平板)叠合板、预应力带肋混凝土叠合板、钢筋桁架叠合板、预应力混凝土钢管桁架叠合板的对比,发现无论大小跨度,预应力混凝土钢管桁架叠合板的应用均占据显著优势。底板中施加预应力和钢管桁架的设置使预应力混凝土钢管桁架叠合板在施工阶段具有较大抗弯刚度。将底板厚度、桁架高度作为参数计算对比各种叠合板施工阶段抗弯刚度。对预应力混凝土钢管桁架叠合板,探讨钢管直径、壁厚对底板抗弯刚度、钢管长细比的影响。得出结论:预应力混凝土钢管桁架叠合板无论钢管是否灌浆在施工阶段都有较大优势,是否灌浆可根据抗弯刚度需求及施工水平确定。

大跨长联钢-混组合梁桥面板预制胶拼施工技术

孟加拉国帕德玛大桥主桥上部结构为6×(6×150) m+1×(5×150) m七联大跨度连续钢-混组合梁。公路桥面设有平曲线,桥面板底部设横肋、板内设纵向预应力钢绞线,桥面板剪力钉(环)槽口边缘与钢梁剪力钉(环)间距小,槽口内纵、横钢筋多且与剪力钉(环)间距小,混凝土桥面板的预制、安装精度和质量控制要求高。桥面板分块整幅在预制场匹配预制,桥上通过胶拼连接,然后分区段进行永久预应力筋张拉、孔道压浆、剪力钉(环)槽口混凝土灌注,将混凝土桥面板与连续钢桁梁组合。混凝土桥面板采用长短线结合匹配预制技术,节省了模板和场地投入,保证了预制精度和预制速度;采用架板机拼装、胶拼连接、分区段张拉永久预应力筋、钢梁上铺设滑动层减少预应力张拉损失、灌注剪力钉(环)槽口混凝土进行组合等安装技术,完成了大跨长联钢桁梁桥公路桥面板的安装施工。