Hysteretic behavior of post-tensioned precast segmental CFT double-column piers

Considering the desirable behavior of concrete filled steel tube(CFT)columns and the complicated behavior of segmental double-column piers under cyclic loads,three post-tensioned precast segmental CFT double-column pier specimens were tested to extend their application in moderate and high seismicity areas.The effects of the number of CFT segments and the steel endplates as energy dissipaters on the seismic behavior of the piers were evaluated.The experimental results show that the segmental piers exhibited stable hysteretic behavior with small residual displacements under cyclic loads.All the tested specimens achieved a drift ratio no less than 13%without significant damage and strength deterioration due to the desirable behavior of CFT columns.Since the deformation of segmental columns was mainly concentrated at the column-footing interfaces,the increase of the segment numbers for each column had no obvious effects on the loading capacity but reduced the initial stiffness of the specimens.The use of steel endplates improved the bearing capacity,stiffness and energy dissipation of segmental piers,but weakened their self-centering capacity.Fiber models were also proposed to simulate the hysteretic behavior of the tested specimens,and the influences of segment numbers and prestress levels on seismic behavior were further studied.

Influence of Steel and Carbon Fiber Reinforcement Bars on Seismic Performance of Precast Segmental Bridge Columns

为了得到快速施工和利用新材料的预制节段桥墩设计方法，研究了部分钢筋替换为碳纤维筋时预制节段桥墩的水平承载力和破坏等级．首先通过与拟静力试验结果的比较证明了仿真分析的正确性，然后研究了部分普通钢筋替换为碳纤维筋，对拟静力循环荷载和地震地面运动分别作用时预制节段桥墩响应的影响．结果表明：碳纤维筋能提高桥墩水平承载力，增大有效刚度，降低等效粘滞阻尼比和滞回能量耗散．地震时程计算表明：部分普通钢筋替换为碳纤维筋时，使得预制节段桥墩在较强烈地震底面运动下不倒塌．利用绝对能量法分析了桥墩在地震地面运动下的能量吸收和耗散情况，并主要研究了4种桥墩试件在3种不同地震地面运动作用下的输入能量和滞回能量耗散，结果是随着桥墩输入地震能量的增大滞回能量耗散增长缓慢．

Seismic behavior of precast segmental column bridges under near-fault forward-directivity ground motions

Precast segmental column bridges exhibit various construction advantages in comparison to traditional monolithic column bridges.However,the lack of cognitions on seismic behaviors has seriously restricted their applications and developments.In this paper,comprehensive investigations are conducted to analyze the dynamic characteristics of precast segmental column bridges under near-fault,forward-directivity ground motions.First,the finite-element models of two comparable bridges with precast segmental columns and monolithic columns are constructed by using OpenSees software,and the nonlinearities of the bridges are considered.Next,three different earthquake loadings are meticulously set up to handle engineering problems,namely recorded near-and far-field ground motions,parameterized pulses,and pulse and residual components extracted from real records.Finally,based on the models and earthquake sets,extensive explorations are carried out.The results show that near-fault forward-directivity ground motions are more threatening than far-field ones;precast segmental column bridges may suffer more pounding impacts than monolithic bridges;the“narrow band”effect caused by near-fault,forward-directivity ground motions may occur in bridges with shorter periods than pulse periods;and pulse and residual components play different roles in seismic responses.

Cyclic performance and simplified pushover analyses of precast segmental concrete bridge columns with circular section

In recent years, precast segmental concrete bridge columns became prevalent because of the benefits of accelerated construction, low environmental impact, high quality and low life cycle costs. The lack of a detailed configuration and appropriate design procedure to ensure a comparable performance with monolithic construction has impeded this structural system from being widely used in areas of high seismicity. In this study, precast segmental bridge column cyclic loading tests were conducted to investigate the performance of unbonded post-tensioned segmental bridge columns. One monolithic and two precast segmental columns were tested. The preeast segmental column exhibited minor damage and small residual displacement after the maximum 7% cyclic drift; energy dissipation （ED） can be enhanced byadding ED bars. The experimental results were modeled by a simplified pushover method （SPOM）, as well as a fiber model （FIBM） finite element method. Forty-five cases of columns with different aspect ratios, axial load ratios and ED bar ratios were analyzed with the SPOM and FIBM, respectively. Using these parametric results, a simplified design method was suggested by regressive analysis. Satisfactory correlation was found between the experimental results and the simplified design method for preeast segmental columns with different design parameters.

Dynamic response of precast segmental bridge columns under heavy truck impact

Considering the wide application of precast segmental bridge columns(PSBCs)in engineering practice,impact-resistant performance has gained significant attention.However,few studies have focused on PSBCs subjected to high-energy impacts caused by heavy truck collisions.Therefore,the behavior of PSBCs under a heavy truck impact was investigated in this study using high-fidelity finite element(FE)models.The detailed FE modeling methods of the PSBCs and heavy trucks were validated against experimental tests.The validated modeling methods were employed to simulate collisions between PSBCs and heavy trucks.The simulation results demonstrated that the engine and cargo caused two major peak impact forces during collision.Subsequently,the impact force,failure mode,displacement,and internal force of the PSBCs under heavy truck impacts were scrutinized.An extensive study was performed to assess the influence of the section size,truck weight,impact velocity,and number of precast segments on the impact responses.The truck weight was found to have a minor effect on the engine impact force.Damage was found to be localized at the bottom of the three segments,with the top remaining primarily undamaged.This parametric study demonstrated that larger cross-sections may be a preferred option to protect PSBCs against the impact of heavy trucks.

装配式桥梁板玻璃纤维混凝土-U形钢筋湿接缝受力与变形分析

为解决装配式桥梁板体系湿接缝处力学性能不稳定、易变形的问题,提出采用玻璃纤维混凝土-U形钢筋加强方案优化湿接缝性能,以雄安新区荣乌高速荣乌主线桥为背景进行研究。选取主线桥2个试验段(试验段A湿接缝采用普通混凝土-U形钢筋方案,钢筋点焊;试验段B湿接缝采用玻璃纤维混凝土-U形钢筋加强方案,钢筋满焊)进行梁板体系湿接缝性能试验,监测湿接缝处搭接钢筋力学响应及混凝土接触面变形特征,同时对长期运载及强降雨影响下的钢筋受力与混凝土变形进行监测。结果表明:长期运载下,试验段B横筋受力约为试验段A的一半,其中部纵筋承受外力远大于试验段A,边缘纵筋承受外力较少,试验段B稳定性更优;试验段B较试验段A在湿接缝部位变形量小,其稳定性及耐久性更优;强降雨阶段,试验段B较试验段A变形及力学响应波动程度更低,其抗渗能力、耐久性更优。由此可知基于玻璃纤维混凝土-U形钢筋加强方案的湿接缝构造在外力传导、抵抗变形方面具有较强稳定性,不易受恶劣环境影响。

采用大直径灌浆套筒连接的预制桥墩抗震性能研究

为探究墩台处采用大直径灌浆套筒连接的预制装配式桥墩抗震性能,进行拟静力试验及有限元分析。设计、制作2个采用大直径灌浆套筒(主筋直径40 mm)连接的预制装配式桥墩(预制桥墩)及1个现浇桥墩开展拟静力试验,对2类试件的试验现象、破坏形态、滞回曲线和承载能力进行对比分析,并采用有限元法对预制桥墩混凝土、套筒及连接钢筋的受力性能进行研究。试验结果表明:在水平循环荷载作用下,预制桥墩与现浇桥墩一致表现为弯剪破坏,但墩底区域破坏形式不同,现浇桥墩主要表现为柱脚混凝土大面积压碎,而预制桥墩的破坏现象更为严重,集中表现为套筒四周混凝土成块压碎剥落;相较于现浇桥墩,预制桥墩的承载能力平均值偏小5.2%,位移延性系数平均值偏小2.7%,预制桥墩力学性能与现浇桥墩相当。有限元分析结果表明:预制桥墩会在套筒顶部和桥墩底部出现2个塑性区,且预制桥墩中大直径灌浆套筒的受力状态以轴向受力为主,按照轴向受力进行套筒设计可满足其在桥墩结构中的受力要求;预制桥墩在墩底混凝土破坏后,其主筋和灌浆料仍保持可靠粘结,采用大直径灌浆套筒连接的预制桥墩抗震性能良好。

爆炸荷载下预制节段拼装双层钢管混凝土墩柱的动力响应数值模拟

为提升装配式公路桥梁的抗爆防护能力,提出了一种新型预制节段拼装双层钢管混凝土(PS-CFDST)组合墩柱.基于非线性显式动力分析程序LS-DYNA建立了新型PS-CFDST墩柱在爆炸荷载作用下动力响应分析的精细有限元模型,并通过已有试验结果验证了模型的准确性.对爆炸荷载作用下PS-CFDST墩柱的动力响应进行数值模拟分析,研究了PS-CFDST墩柱在爆炸荷载作用下的破坏过程、损伤机理和耗能机制.运用参数化分析方法,研究了爆炸距离、节段数量和预应力水平等关键参数对PS-CFDST墩柱动力响应的影响,并在此基础上提出了PS-CFDST墩柱的抗爆设计建议.结果表明:PS-CFDST墩柱除通过材料塑性损伤耗能之外,节段接缝界面滑移耗能机制对耗能贡献可达40%以上;增大墩柱可接近距离是提升墩柱抗爆安全性的有效手段,增大预应力有利于减小柱中最大水平位移和墩底剪切滑移,从而提升PS-CFDST墩柱的抗爆性能.

既有节段预制混凝土桥梁状态评估方法研究

基于国内外学者关于既有桥梁状态评估方法的研究,建立既有节段预制桥梁结构损伤状态评估指标体系.提出基于层次分析法的既有节段预制桥梁状态评估方法,并在该方法的基础上,引入权重赋分法考虑各影响因素的重要程度对既有节段梁各结构进行权重赋分,给出了相应的桥梁状态评估公式,制定了节段预制桥梁状态评估标准.最后,结合一个既有节段预制桥梁损伤状态评估实例来演示本文所提出方法进行节段梁状态评估的实现过程.

地面爆炸作用下地下综合管廊动力响应的实验研究

为研究地下综合管廊结构的抗外部爆炸性能,针对整体现浇管廊和预制节段拼装管廊结构在地面爆炸作用下的动力响应特性和破坏模式开展了野外爆炸实验研究。通过11个工况的野外爆炸实验,观测了现浇管廊和预制节段拼装管廊在不同比例距离爆炸工况下的破坏特征和动力响应,对比分析了现浇管廊和预制节段拼装管廊的抗爆性能。结果表明:在地面爆炸作用下,现浇管廊和预制节段拼装管廊的顶板最终均出现弯剪破坏,整体现浇管廊的抗爆性能总体上优于预制节段拼装管廊。起爆位置对预制节段拼装管廊爆炸响应的影响较大,在节段中心上方起爆时结构损伤最严重。在小比例距离地面爆炸作用下,现浇管廊的损伤区域大于预制节段拼装管廊,预制节段拼装管廊的损伤集中在近爆心下方所在的节段或连接接缝处,节段间可产生较大残余滑移。

承插式连接预制拼装桥墩抗震性能试验研究

为研究不同连接构造、轴压比和承插深度对承插式连接预制拼装桥墩(简称“承插式桥墩”)抗震性能的影响,制作1组现浇桥墩试件和3组承插式桥墩试件开展拟静力试验。对比试件破坏模式、滞回曲线、骨架曲线及特征值、耗能能力、刚度特性和残余位移、纵筋应变,分析承插式桥墩与现浇桥墩抗震性能差异以及增设钢榫进行结构优化后桥墩抗震性能改善效果。结果表明:承插式桥墩与现浇桥墩试件破坏模式、损伤范围、承载能力、耗能能力、残余位移和钢筋应变沿梁高分布相近;提高承插式桥墩轴压比,能提高桥墩承载能力,降低延性和累积耗能能力,破坏时残余位移远小于其它构件,具有可靠的自复位能力;提高承插深度,会增大桥墩承载能力和耗能能力;墩底增设钢榫能增强承插式桥墩与承台间的连接,承载能力、延性、耗能能力等与承插式和现浇桥墩保持一致,但各加载位移下的累积耗能较高,有助于提高承插式桥墩的耗能能力,具有良好的抗震性能。

冻融循环作用下节段预制全胶接拼装梁剪力键抗剪承载力研究

为分析冻融循环对节段预制全胶接拼装混凝土梁剪力键抗剪承载力的削弱效应,建立剪力键抗剪承载力计算模型,并进行单调加载和反复加载模型试验验证,采用冻融材料应力~应变关系曲线,对冻融循环次数、冻融后反复加载、正应力水平、键齿数量、键齿尺寸进行抗剪承载力参数影响分析。结果表明:单调加载、冻融后反复加载的剪力键抗剪承载力与冻融循环次数均呈二次抛物线关系;冻融循环次数对剪力键抗剪承载力有较大削弱;冻融循环后再反复加载,剪力键抗剪承载力进一步明显降低。单调加载下,剪力键抗剪承载力和正应力呈线性正相关;剪力键抗剪承载力与键齿数量呈三次抛物线关系,键齿数量超过4个,抗剪承载力随键齿数量增多增长缓慢;剪力键抗剪承载力与键齿尺寸比呈线性正相关。

悬臂拼装施工的预制节段箱梁桥预应力参数优化

为揭示预制节段箱梁桥预应力相关参数对悬臂拼装阶段和合龙阶段箱梁横截面应力及施工期线形的影响,选取某工程一联三跨预制节段箱梁桥,针对悬臂拼装阶段和合龙阶段不同预应力参数取值对桥梁受力状态及变形特征的影响进行数值模拟。研究结果表明:预制节段箱梁桥顶板钢束最优张拉控制应力为预应力钢束抗拉强度标准值的0.70~0.75倍,与此同时应控制预应力钢束截面积不低于0.000 98 m^(2)(7Ф15.2 mm)。顶板单侧钢束组预应力合力作用线与顶板中轴线之间的距离,即顶板预应力合力偏心距宜取箱梁宽度的0.22~0.26倍。合龙阶段采用先张拉底板、腹板通长钢束,再张拉中、边跨局部钢束的方式可使桥梁在不同张拉阶段之间的线形及横截面应力变化更加平缓,有利于施工期间结构的安全控制。

自复位预制节段桥墩抗震性能试验研究

为提高装配式预制桥墩的抗震性能以及解决震后可修复的问题,本文基于后张无黏结预应力筋的连接技术,提出了一种新型自复位预制节段桥墩(self-centering precast segmental bridge pier,SPSBP)。该新型自复位预制节段桥墩由预制构件(盖梁、节段、基础)、可更换耗能角钢和连接钢板组成。本文设计并完成了三组SPSBP试件的拟静力试验,研究初始预应力、耗能角钢厚度以及长度三个参数对SPSBP试件抗震性能的影响。试验结果表明:该新型结构形式具有较好的自复位以及耗能能力;当加载到最大位移比时,试件变形主要集中于耗能角钢,主体预制结构并未发生明显破坏,表明了结构的完整性;提高初始预应力能有效提高结构的承载力等抗震性能并减小残余变形;增加耗能角钢厚度,可以提高SPSBP耗能能力以及承载力;耗能角钢长度对SPSBP性能影响不明显。

小半径曲线节段拼装箱梁设计和施工关键技术研究

为推动小半径曲线节段拼装箱梁在立交匝道桥梁中的应用,对该类桥梁受力特性、合理构造以及梁段制造、架桥机施工、拼装线形控制等关键技术进行研究。分析曲线半径对该类箱梁弯扭耦合和湿接缝受力的影响;研究梁高、腹板厚度和顶、底板厚度对梁剪扭承载力的影响;为适应平面曲线行走和吊装的需求,总结架桥机拼装施工过程中主要采用的转弯过孔、偏位和斜置起吊调整以及尾部喂梁关键技术;分析拼装过程中产生的轴线偏差和横向位移及线形控制措施。结果表明:曲线半径小于250 m的节段拼装箱梁需考虑弯扭耦合作用,曲线半径小于100 m时湿接缝截面的抗扭承载力和剪扭允许应力已不能满足要求;提高截面抗剪扭承载力最有效的构造措施是增加腹板厚度,其次是增加顶、底板厚度;曲线半径越小,小半径节段梁拼装轴线偏差越大、轴线横向位移越大,应根据曲线半径来规定安装精度验收标准、根据成桥轴线横向变形设置横向预拱度。

外置拱形耗能装置的节段拼装钢管混凝土桥墩抗震性能分析

为了进一步推广可恢复功能的预制装配式桥梁结构在中、高烈度地区的应用,减少桥墩的震后损伤及修复成本,提出一种外置拱形耗能装置的节段拼装钢管混凝土(concrete-filled steel tube,CFST)桥墩。基于ABAQUS有限元分析软件建立无耗能装置、外置拱形钢板、外置竖直钢板、外置拱形耗能装置的四节段预制拼装CFST桥墩模型,并在往复位移加载作用下对各模型的抗震性能进行对比分析。研究结果表明:外置拱形耗能装置的预制节段拼装CFST桥墩具有较好的水平承载力、较高的初始刚度以及较强的耗能能力,与外置竖直钢板的节段拼装CFST桥墩相比,其抗侧承载力提升了约11.9%,初始刚度提升了约2.5%;与外置拱形钢板的节段拼装CFST桥墩相比,其抗侧承载力、初始刚度以及耗能能力分别提升了约28.8%、4.6%和13倍;与无耗能装置的预制拼装CFST桥墩相比,其抗侧承载力、初始刚度以及耗能能力分别提升了约39.4%、10.4%和18.1倍;外置拱形耗能装置的预制节段拼装CFST桥墩在整个位移加载阶段残余位移均保持在1 mm之内,偏移率不超过1%,且损伤集中在拱形耗能装置上,能够实现震后的快速修复。

纤维增强混凝土预制隧道管片结构性能研究

为研究纤维增强混凝土预制隧道管片抗弯性能、抗裂性能及隧道掘进机产生的推力对管片的影响,对钢筋混凝土管片和纤维增强混凝土管片进行全尺寸试验,包括静载弯曲试验和点荷载试验。研究结果表明,从设计荷载角度考虑,纤维增强混凝土管片相对于钢筋混凝土管片具有更高的承载力;钢筋混凝土管片和纤维增强混凝土管片点荷载⁃位移关系曲线变化趋势较相似,管片均未发生明显的开裂,均能承受设计荷载作用;与钢筋混凝土管片相比,纤维增强混凝土管片具有更好的抗弯性能和抗裂性能,纤维增强混凝土可替代钢筋混凝土制备预制隧道管片。

城市立交异形变宽预制节段箱梁设计关键技术研究

结合城市立交常见的变宽形式,对异形变宽预制节段箱梁进行设计构思,提出合理的变宽方案,分析变宽预制节段箱梁的受力性能,并对其关键结构进行优化,以提高变宽预制节段箱梁的标准化程度和拼装效率,拓宽预制节段箱梁在城市立交桥梁中的应用范围,对同类型桥梁的设计工作具有一定的借鉴价值。

预制混凝土节段胶拼构件接缝粘接机理及耐久性研究

为了提高混凝土胶接的可靠性和安全性,分析了胶接缝耐久性能与粘接性能影响因素。重点设计了预制混凝土节段胶接缝耐久性试验,制备拼接胶拉伸试件和节段预制胶拼构件,在不同试验环境下进行拉伸破坏。并分析了胶拼构件接缝界面粘接机理,为提高拼接胶与混凝土界面的粘接强度提供参考。试验结果表明,人工加速湿热老化环境下拼接胶拉伸试件的强度比40℃高温环境下降了7.3%;人工加速湿热老化环境下胶拼构件破坏类型为混合破坏,自然环境下均为混凝土内聚破坏,自然环境处理下胶接缝的耐久性更好,抗拉强度高12.2%左右。

验潮站井筒结构节段预制拼装下放工艺研究与应用

湛江港验潮站预制井筒结构长9.5 m,重18 t,距验潮站2.5 m处的码头泊位服役近30 a,经检测表明其承载能力不足,码头泊位无法满足大型起重设备进场作业,预制井筒结构整段吊装存在困难。为此研究类工厂化的井筒结构段预制拼装下放工艺,实现场内分段预制,施工现场小型起重设备起吊,边拼装边下放。研发了相应的拼装接头、拼装下放工艺、拼装控制技术和下放装置。通过工程应用验证,验潮站井筒结构节段预制拼装下放工艺有效避免了对大型起重设备的依赖性,有良好的推广应用价值。