Discussion on Detection and Evaluation of Simply Supported Prestressed Concrete Small Box Girder Bridge After a Fire

The article takes a simply supported prestressed concrete small box girder bridge project as an example for inspection and evaluation after a fire incident.This includes appearance detection,concrete color hardness detection,concrete strength detection,concrete surface damage layer detection,reinforcement protective layer detection,and concrete carbonation detection.It is hoped that this analysis can be used as a reference for the detection and evaluation of future bridge projects with fire incidents to smoothen its subsequent repair and maintenance.

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 .

Finite element failure analysis of continuous prestressed concrete box girders

In order to analyze the load carrying capacity of prestressed concrete box girders, failure behaviors of in-situ deteriorated continuous prestressed concrete box girders under loading are experimentally observed and a finite failure analysis method for predicting behaviors of box girders is developed. A degenerated solid shell element is used to simulate box girders and material nonlinearity is considered. Since pre-stressed concrete box girders usually have a large number of curve prestressed tendons, a type of combined element is presented to simulate the prestressed tendons of box girders, and then the number of elements can be significantly reduced. The analytical results are compared with full-scale failure test results. The comparison shows that the presented method can be effectively applied to the failure analysis of in-situ continuous prestressed concrete box girders, and it also shows that the studied old bridge still has enough load carrying capacity.

Weakening effect of vertical prestress ducts on web sections in prestressed concrete box girder bridges

Based on experimental study result of two simply supported beams,which were prestressed by vertical tendons,the research on the weakening effect of vertical prestress ducts on web sections of prestressed concrete box girder was carried out. The test result shows that in the condition without grouting into the ducts,the cracking load is evidently lower than that with full grouting,and stirrup stress and principal tension stress at the surface of concrete will increase obviously. Meanwhile,the finite element analysis has been done to the test beams. The research is consistent with the analysis of finite element. The research tells that strengthening the detection and management for the vertical prestress grouting quality have an important meaning to prevent cracking of the prestressed concrete box girder bridge and provide one theoretical and testing basis for analyzing the cracking reason of such bridges.

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.

Full-scale model tests and nonlinear analysis of prestressed concrete simply supported box girders

Full-scale model tests were carried out on a 30 m span prestressed concrete box girder and a 20 m span prestressed concrete hollow slab. Failure models were prestressed reinforcement tensile failure and crashing of roof concrete, respectively. The ductility indexes of the box girder and hollow slab were 1.99 and 1.23, respectively, according to the energy viewpoint. Based on the horizontal section hypothesis, the nonlinear computation procedure was established using the limited banding law, and it could carry out the entire performance analysis including the unloading, mainly focusing on the ways to achieve the unloading curves computation through stress-strain, moment-curvature and load-displacement curves. Through the procedure, parameters that influence on the bearing capacity, deformation performance and ductility of the structures were analyzed. Those parameters were quantity of prestressed reinforcement and tension coefficients of prestressed reinforcement. From the analysis, some useful conclusions can be obtained.

Simulation of Temperature Field in Original Segment of Concrete Box-Girder Bridge

Temperature field and its variation with time are necessary for analyzing the thermo-mechanical performance of mass concrete structures at their early ages. This paper carries out a temperature field simulation analysis for an original segment of a real box girder bridge with the finite element software ANSYS. Two representative exothermic rate models are used to describe the heat- releasing process caused by the cement hydration in concrete. The exothermic rate model that conforms to reality more closely is recognized by comparing the simulation results with the data gathered from the optical fiber temperature sensors pre-embedded in the original segment. The air temperature and wind velocity that constitute thermal boundary conditions are determined in the light of the local meteorological department and correlative research achievements of recent years. Moreover, the consideration for the steel formwork acting as a barrier to heat loss is also proved to be beneficial to improve the simulation effect.

Temperature distributions in concrete box girders due to heat of concrete hydration

Based on heat transfer theory,a two-dimensional complex exponential function was used to compute heat of concrete hydration.A concrete box girder consisting of a single box with two cells used on Harbin Songpu Bridge was measured on site.The two coefficients in the complex exponential function were determined to best fit the field measured data.ABAQUS program was used to simulate the heat transfer and determine the temperature distribution in the concrete box girders during concrete setting.The calculated temperature distribution in the box girders were compared with the field measured data and good agreement was observed.The temperature distribution and gradient in the entire box section,webs and bottom slab were analyzed using the measured and calculated results during the course of concrete hydration.

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.

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.

简支变结构连续小箱梁桥负弯矩区UHPC-NC组合桥面板抗裂性研究

针对当前简支变结构连续小箱梁桥负弯矩区钢束易堵孔、运营中桥面开裂病害等问题,提出一种无负弯矩钢束的UHPC-NC组合桥面板结构。以一座3×30 m简支变结构连续小箱梁桥为研究对象,以正常使用极限状态梁体不开裂为控制准则确定UHPC合理构造尺寸,对所提出的负弯矩组合桥面板结构进行1∶2的缩尺模型试验。试验显示:裂缝首先出现于UHPC-NC交界面处的普通混凝土部分,随后逐渐向UHPC层沿伸,且C50混凝土开裂、梁体破坏对应的截面弯矩分别为3 520,9 152 kN·m(考虑1∶8弯矩缩尺比),大于正常使用极限状态、承载能力极限状态梁体截面弯矩3 300,5 838 kN·m,即该组合桥面板结构满足小箱梁的抗裂与承载能力要求。基于试验结果建立精细化有限元模型,采用参数分析法研究UHPC厚度对梁体开裂荷载、极限承载力等方面的影响。结果表明:梁体开裂弯矩主要由UHPC上覆层厚度决定,相较于普通钢筋混凝土梁,5 cm厚的UHPC上覆层可将梁体开裂弯矩提高28.9%,7.5 cm厚的UHPC上覆层可将梁体开裂弯矩提高41.6%;在配筋率不变的情况下,增大UHPC层厚度对梁体承载力无显著提升。综合考虑梁体受力性能以及施工便利性,建议背景工程UHPC厚度取10 cm。

简支波形腹板钢箱组合截面与传统截面箱梁桥抗震性能对比分析

为研究波形腹板钢箱-混凝土组合梁桥(CW-SBCCGB)与传统箱梁桥抗震性能的异同,基于截面等效原理,根据某实际工程CW-SBCCGB的单箱截面,等效出波形腹板混凝土箱梁桥(CW-CBGB)和混凝土箱梁桥(CBGB)的单箱截面,再结合动力分析理论和ABAQUS有限元模型对比分析3种截面简支梁桥动力特性和抗震性能的不同。结果表明:3种截面简支梁桥前五阶振型不变,CW-CBGB和CBGB前三阶频率相比于CW-SBCCGB有所下降,但相差不超过1Hz,第四阶及以后频率差异逐渐变大;剪滞效应对CW-SBCCGB和CW-CBGB动力特性影响较大,对CBGB影响较小;在纵桥向+竖桥向和横桥向+竖桥向地震作用下,CW-SBCCGB和CBGB的墩顶位移和跨中位移均大于CW-CBGB结构,CW-SBCCGB主梁跨中截面剪力最小,CW-CBGB跨中截面弯矩最小,说明CW-SBCCGB和CW-CBGB的抗震性能均优于CBGB的抗震性能。

某单箱三室连续梁桥静载试验研究

为测试某单箱三室连续梁桥整体受力特点,检验桥跨结构的承载能力、结构变形是否满足在正常使用状态下的设计要求,通过Midas/Civil对该桥进行有限元分析,并进行了静载试验研究,测试在静载试验下,各控制截面的应变状态和整体挠度,试验结果表明,各控制截面应变与挠度值实测结果与理论结果基本一致,且与之对应的校验系数在规定范围内,该桥强度和刚度均满足设计要求,桥跨结构的承载能力、结构变形在正常使用状态下均符合设计要求;在加载试验前后,对测试截面附近进行了裂缝观测,没有发现新增裂缝,试验桥跨结构承载力满足设计荷载标准要求。

多跨预应力混凝土连续梁整体平移改造施工关键技术

宿迁古黄河老桥为(22.5+3×30+22.5)m四幅分离式连续梁桥,两侧为非机动车道桥,中间为机动车道桥。由于该桥位于生态保护区且梁体质量良好,为满足迎宾大道二期快速化改造需要,采取在不中断交通的前提下,通过交通导改先后将西侧和东侧机动车道桥分别往两侧整体平移3.25 m,再于中间修建新桥的改造方案。结合桥位处水文地质情况,采用在非机动车道桥外侧设置“钢板桩+过水钢管”围堰进行无水条件下的基础墩身拼宽施工。改造施工时,根据单侧机动车道桥支座处顶升荷载及梁底空间选配布置顶升千斤顶和步履器;通过有限元计算确定梁体顶升与平移施工过程中各支点竖向和横向位移偏差控制指标,采用PLC液压同步控制系统操控步履器与千斤顶交替顶升与平移,既能保证梁体整体顶升与平移的精度又能有效控制梁体应力突变;待梁体平移到设计位置后,拆除步履器和顶升千斤顶,复原垫石、支座及挡块。

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。

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。

预应力混凝土箱梁爆炸荷载模型试验及有限元分析

目前针对箱梁爆炸荷载以及冲击波传播规律的研究较少,以目前混凝土桥中应用较为广泛的预应力混凝土箱梁桥为依托工程,以1∶5缩尺比例设计箱梁爆炸荷载试验。试验表明,箱梁顶板超压沿箱梁纵向呈非线性下降梯度分布特点,超压沿箱梁横向近似于梯形荷载分布,随着比例距离的减小,结构超压增大。其次,基于箱梁爆炸荷载试验,建立箱梁三维爆炸数值分析模型,通过将数值分析结果和试验数据进行对比,验证数值模拟的准确性。基于数值分析,揭示爆炸冲击波与箱梁的相互作用机理,明确箱梁冲击波的传播规律。对不同爆炸工况箱梁各部位超压分布规律研究显示:当爆心位于箱梁顶板上方时,顶板迎爆面超压较大;当爆心位于翼缘板下方时,在翼缘和腹板处产生较大超压,其余部位超压较小。而当爆心位于箱梁底板下方时,翼缘、腹板和底板均受到较大的冲击波超压,结构全截面受爆炸影响较大。最后,基于试验和数值分析结果,对不同工况下箱梁顶板、腹板和底板的超压峰值进行方程拟合,建立不同爆炸工况下箱梁关键部位荷载模型。

基于BP神经网络的混凝土箱梁最大温度梯度预测

混凝土箱梁受到太阳辐射、大气温度波动等多种气象因素的综合作用,结构内部会产生显著的非均匀温度分布。截面内温度梯度可能会导致桥梁结构产生过大的温度应力与温度变形,影响桥梁结构的安全性和耐久性。本文旨在探究气象因素对混凝土箱梁温度场的影响机理,并提出一种能精确预测中国多区域混凝土箱梁截面最大温度梯度的方法。首先建立了日照条件下混凝土箱梁温度场计算模型,将2 a以上气象资料作为输入条件,对多个地区混凝土箱梁温度场长期变化进行了仿真模拟,并对混凝土箱梁截面温度梯度的长期变化趋势进行了分析。然后利用主成分分析(PCA)确定了混凝土箱梁截面最大温度梯度预测模型所需的输入参数。最后利用遗传算法优化的BP神经网络建立预测混凝土箱梁竖向、横向温度梯度的网络模型,并与混凝土箱梁截面温度梯度进行比较。结果分析表明BP神经网络模型可以精确地预测混凝土箱梁最大温度梯度,预测值平均绝对误差(AAE)均小于0.9℃,均方根误差(RMSE)均小于1.2℃,决定系数(R^(2))均大于0.9。基于当地气象条件,本文利用经典的BP神经网络模型所建立的预测模型对中国不同地区的混凝土箱梁截面最大温度梯度均能给出准确的预测,为混凝土箱梁设计和施工阶段的最大温度梯度的计算提供一种高效的方法。

两跨独柱墩曲线连续钢箱梁抗倾覆设计方法

独柱墩曲线连续钢箱梁是城市立交匝道桥常用的结构形式,但因其存在支座间距小、内外侧支座支反力差别大、边墩支反力小以及钢箱梁自重轻等诸多缺点,所以抗倾覆性能差便成为此类桥型普遍存在的问题。近年来发生的数十起该类型的桥梁倾覆事故,造成了严重的社会影响及经济损失。依据相关规范中关于桥梁上部结构抗倾覆计算方法,以实际工程为例,对两跨独柱墩曲线连续钢箱梁抗倾覆性能进行计算分析,得出采用双支座并且给主梁边墩位置处配重的方法,并从特征状态1及特征状态2两方面给出了提高该类型桥梁的横桥向抗倾覆性能的设计方法。