Structural Behavior of Continuous Prestressed Steel Fiber Reinforced High Strength Concrete Beam

The flexural behaviors of continuous fully and partially prestressed steel fiber reinforced high strength concrete beams are studied by experiment and nonlinear finite element analysis. Three levels of partial prestress ratio （PPR） are considered, and three pairs of two-span continuous beams with box sections varying in size are designed. The major parameters involved in the study include the PPR and the fiber location. It is concluded that the prestressed high strength concrete beam exhibits satisfactory ductility; the influences of steel fiber on the crack behaviors for partially prestressed beams are not as obvious as those for fully prestressed ones; steel fibers can improve the structural stiffness after cracking for fully prestressed high strength concrete beams; the moment redistribution from mid-span to intermediate support in the first stage should be mainly considered in practical design.

Experimental Behavior of Partially Prestressed High Strength Concrete Beams

In the last few decades, prestressed concrete has been rapidly used in bridge engineering due to the enormous development in the construction techniques and the increasing need for long span bridges. High strength concrete has been also more widely spread than the past. It currently becomes more desirable as it has better mechanical properties and durability performance. Major defect of fully prestressed concrete is its low ductility;it may produce less alarming signs than ordinary reinforced concrete via smaller deflection and limited cracking. Therefore, partially prestressing is considered an intermediate design between the two extremes. So, combining high strength concrete with partial prestressing will result in a considerable development in the use of prestressed concrete structures regarding the economical and durability view points. This study presents the results of seven partially prestressed high strength concrete beams in flexure. The tested beams are used to investigate the influence of concrete compressive strength, prestressing steel ratio and flange width on the behavior of partially prestressed beams. The experimentally observed behaviors of all beams were presented in terms of the cracking load, ultimate load, deflection, cracking behavior and failure modes.

Experimental Study on Flexural Behavior of Post-Tensioning Bonded Partially Prestressed Ultra-High Strength Concrete Beams

This paper presents the results of four partially prestressed ultra-high strength concrete beams in flexure. The test results are used to evaluate the effects of prestressing tendon depth and area on flexure behavior of specimen beams. The test results indicate that: the cracking load,yielding load,peak load and stiffness postcracking of specimen beams are enhanced by reducing prestressing tendon depth or increasing prestressing tendon area, and the flexural ductility is improved by increasing prestressing tendon depth or reducing prestressing tendon area. The effect of complex reinforcement index considering the strength of the equivalence principle and the reinforcement position on loading levels under serviceability limit state,flexural strength and displacement ductility factor are studied. The influence coefficient of prestressing tendon kpis introduced in the complex reinforcement index. As the complex reinforcement index increases, the loading levels under serviceability limit state and flexural strength increases linearly,and the displacement ductility factor decreases linearly. The test results also verify the conventional beam flexural theory based on the plane cross-section assumption for predicting ultimate flexural strength of partially prestressed ultra-high strength concrete beams is valid. After the introduction of the coefficient kp,the calculation method of cracks in code for design of concrete structure in china are appropriated for the specimen beams.

Shear design of high strength concrete prestressed girders

Normal strength prestressed concrete I-girders are commonly used as the primary superstructure components in highway bridges. However, shear design guidelines for high strength PC girders are not available in the current structural codes. Recently, ten 7.62 m （25 feet） long girders made with high strength concrete were designed, cast, and tested at the University of Houston （UH） to study the ultimate shear strength and the shear concrete contribution （Vc） as a function of concrete strength （f＇c）. A simple semi-empirical set of equations was developed based on the test results to predict the ultimate shear strength of prestressed concrete I-girders. The UH-developed set of equations is a function of concrete strength （√f＇c）, web area （bwd）, shear span to effective depth ratio （a/d）, and percentage of transverse steel （Pt）. The proposed UH-Method was found to accurately predict the ultimate shear strength of PC girders with concrete strength up to 117 MPa （17000 psi） ensuring satisfactory ductility. The UH-Method was found to be not as overly conservative as the ACI-318 （2011） code provisions, and also not to overestimate the ultimate shear strength of high strength PC girders as the AASHTO LRFD （2010） code provisions. Moreover, the proposed UH-Method was found fairly accurate and not exceedingly conservative in predicting the concrete contribution to shear for concrete strength up to 117 MPa （17000 psi）.

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。

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。

轴力对预应力高强混凝土管桩抗震性能的影响

目的研究轴力和往复荷载作用下预应力高强混凝土管桩的抗震性能,为预应力高强混凝土管桩的设计和实际工程应用提供参考依据。方法应用ABAQUS有限元软件对预应力高强混凝土管桩进行有限元模拟,并与已有试验结果对比,两者吻合良好,验证了模型的准确性。在此基础上,研究轴压比和有无普通钢筋及普通钢筋直径对预应力高强混凝土管桩滞回曲线、骨架曲线、刚度退化、延性及耗能能力的影响。结果配置普通钢筋可以提高预应力高强混凝土管桩的承载能力和延性,对刚度影响不大;随着轴压比的增加,预应力高强混凝土管桩的承载能力逐渐提高,但延性变差,轴压比为0.45时,预应力高强混凝土管桩发生脆性破坏。结论配置普通钢筋可以有效改善预应力高强混凝土管桩的抗震性能,预应力高强混凝土管桩的轴压比不宜超过0.3。

体外预应力UHPC无腹筋梁抗剪性能试验研究

为研究体外预应力超高性能混凝土(Ultra-high Performance Concrete,UHPC)无腹筋梁的抗剪性能,设计了3片体外预应力UHPC无腹筋梁,剪跨比分别为1.44、2.56、3.67,采用四点加载的方式进行抗剪性能试验,获得了试验梁的荷载-位移关系、荷载-应变关系、破坏形态以及极限抗剪承载力。试验结果表明:体外预应力UHPC无腹筋梁的抗剪破坏方式均表现为脆性破坏,随着剪跨比的增大,试验梁破坏形态依次表现为斜压破坏、剪压破坏、剪拉破坏;剪跨比越大,斜裂缝的数量越少、倾角越小,试验梁的极限抗剪承载力越小,且减小趋势变缓。基于极限平衡法推导了体外预应力UHPC无腹筋梁的抗剪承载力计算公式,验算了14片无黏结预应力UHPC梁的抗剪承载力,该公式适用性良好。

非挤土嵌岩预应力高强度混凝土管桩的桩端承载性能研究

施工装备和工艺的不断创新使得非挤土嵌岩预应力高强度混凝土(prestressed high-strength concrete,简称PHC)管桩逐渐得到推广和应用。为揭示嵌入中微风化岩PHC管桩的桩端承载机制,以随钻跟管工法桩为背景,基于泥质粉砂岩地区5组桩径为500 mm的PHC管桩桩端现场静载破坏性试验,分析了不同条件下嵌岩PHC管桩的桩端承载性能及宏观破坏模式,并提出桩端承载力计算方法。试验表明:对于采用敞口桩靴的PHC管桩,未封底时,敞口桩靴削弱了PHC管桩桩端承载性能,呈现刺入岩基的破坏,极限荷载下桩端沉降为11~15 mm;混凝土封底后,显著提高了桩端承载性能,极限承载力较非封底时提升340%,封底混凝土和桩靴的桩端阻力分担比分别为78%和22%,桩端呈整体剪切破坏。基于Hoek-Brown强度准则,提出了嵌岩PHC管桩桩端承力简化计算方法,计算精度得到了试验验证,可供非挤土嵌岩PHC管桩的设计与施工参考。

高速公路30 m UHPC无腹筋预应力U型节段组合梁抗弯承载能力足尺试验研究

中开高速公路改扩建工程中首次在高速公路中大规模采用30 m跨度的UHPC无腹筋预应力U型节段组合梁,充分利用了新型桥梁质量轻、整体性好、耐久性优异的特点。成果是世界首次针对这种梁型开展足尺寸抗弯承载能力试验。详细介绍了新型结构的力学特点和试验结果。研究结果表明:UHPC无腹筋预应力U型节段组合梁具有承载能力高、结构延性优异的特点。

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。

预应力混凝土高层建筑稳定性研究

介绍了预应力混凝土结构的基本原理,以及预应力混凝土结构的施工工艺与质量控制措施,通过拟静力试验方法,评估了预应力混凝土在高层建筑墙体稳定性方面的应用效果。试验结果表明,预应力混凝土施工工艺显著提高了墙体的抗裂性和稳定性,减少了裂缝的产生,并在极端情况下仍能保持一定的承载能力。

预应力空心方桩与预应力管桩力学性能比较和经济性分析

对预应力高强混凝土空心方桩(PHS)与预应力高强混凝土管桩(PHC)两种桩型的桩身物理性能和力学性能进行比较分析,并结合工程案例,进一步对两种桩型的单桩竖向承载力、桩基础工程量及造价进行了力学性能及经济性比较,最后对两种桩型的堆放方式进行了简单介绍。

UHPC无腹筋预应力U型组合节段梁接缝直剪足尺试验研究

UHPC节段梁具有结构质量相对轻、施工速度快、维护成本低等特点,如今已应用于许多桥梁工程。节段梁桥接缝中的剪力键是节承载剪力重要的部分,是国内外学者的重点研究对象。依托中开高速公路项目对UHPC无腹筋预应力组合节段梁接缝进行足尺直剪试验,分析研究试验梁的破坏模态,并建立有限元模型进行进一步分析。研究结果表明剪力键稀齿布设是可行的,接缝抗剪承载能力主要由上部剪力键、接缝接触面以及预应力筋来承担。

高速铁路大跨度低高度预应力混凝土连续梁设计研究

为降低铁路大跨度预应力混凝土连续梁高度,扩大其适用范围,提出主跨100 m低高度连续梁合理跨度配比及构造尺寸,计算结果均满足规范要求。通过与常用高速铁路主跨100 m连续梁对比分析,系统研究了跨度配合比、构造参数等对结构的影响,总结出大跨度低高度连续梁的优缺点及构造建议值。研究结果表明:(1)低高度连续梁在同等跨度下混凝土用量更省,每延米混凝土用量降低约20%,较传统连续梁更经济;(2)低高度连续梁由于梁高降低,主梁刚度略有降低,但工后徐变上拱值降低明显,减幅约60%;(3)对于主跨100 m低高度连续梁,建议配跨长度在70~80 m之间,且不宜小于60 m;(4)主跨100 m低高度连续梁墩顶梁高不宜小于6 m,建议取值范围6.0~6.5 m,跨中梁高不宜小于3.0 m,建议取值范围3.0~3.5 m。

高震区高速铁路跨度40m简支箱梁方案可行性研究

高铁40 m简支箱梁为近年新发展的大跨度桥梁建造技术,已在低震区多个项目应用,但尚未见高震区桥梁案例,40 m梁是否适用于高震区高铁桥梁,需要研究分析。以津承高铁天津段为例,对0.2g地震区的桥梁进行了40 m梁跨度比选研究,研究涉及梁墩构造、全桥动力性能、工期和经济比选等多方面。研究结论表明:(1)与32 m梁比,40 m梁每延米圬工量较少,两者预制架设经济指标相当;(2)两种跨度梁的桥墩构造一致,40 m梁实体墩墩顶略大,桥墩配筋较32 m梁加强;(3)40 m梁桥的自振频率、脱轨系数、轮重减载率等动力性能均满足规范要求;(4)40 m梁运架设备充足、工艺较成熟,不是制约40 m梁推广应用的因素;(5)40 m梁桥的地震重要性系数宜取1.5,此时的桥梁地震响应与公路、城市桥梁抗震算法较为接近;(6)两种跨度梁的梁场规模相当,40 m梁的运架工期更节约;(7)0.2g地震区40 m梁方案与32 m梁方案相比,投资增加3.57%,增幅较小,但40 m梁方案综合效益显著,可以作为高震区高铁标准跨度梁推荐使用。

库区公路预应力混凝土简支梁高墩选型研究

以库区公路改建工程项目为背景,选取该库区公路上某座预应力混凝土简支T梁。确定其高墩结构类型后,通过Ansys有限元分析软件对水动力效应下的高墩进行抗震分析,为库区公路预应力混凝土简支T梁高墩设计提供一定的参考。

特高压输电线路工程PHC管桩基础造价研究

预应力高强混凝土管桩(PHC管桩)的应用存在局限性,近年来特高压输电线路工程在不断摸索和优化PHC管桩的差异化应用,虽然在应用技术方面相对已经比较成熟,但关于其综合造价的对比分析尚缺乏深入研究。为研究PHC管桩在实际工程应用的经济性,文章以典型直流特高压输电线路工程为例,通过与灌注桩基础方案的横向对比,结合输电线路取费、综合造价方面对PHC管桩进行研究。研究发现,PHC管桩的本体造价高于灌注桩基础23%~33%,但其他费用均低于灌注桩基础。当基础作用力小、地质条件较好时,PHC管桩的综合造价具有经济优势。

高压旋喷注浆在预应力管桩桩身缺陷处理中的应用

预应力管桩广泛应用于各类工程建设中,但在实际工程中经常会因为地质、施工等因素造成桩身缺陷,缺陷的修复效果直接影响到后期的施工进度、施工成本等。通过几种预应力管桩修复手段的机理入手,结合实际预应力管桩修复工程案例,根据桩身缺陷修复前后试验结果对比,得出高压旋喷注浆对于预应力管桩桩身缺陷修复具有良好效果。

上承式钢管混凝土拱桥桥道系病害分析和加固

为了研究在役上承式钢管混凝土拱桥桥道系结构病害产生的原因,梳理桥梁历年养护情况,建立全桥有限元模型和上部结构单梁模型,进行影响因素分析。分析表明:T梁承载能力下降导致大量U型裂缝产生,主拱圈温度作用下的变形、桥道系自身整体性不足导致桥面铺装开裂。提出一种改进的体外预应力布置方式以提升T梁承载能力,并利用有限元分析验证其加固效果,采用超高性能混凝土重做现浇层和T梁横隔板包钢增强桥面铺装韧性和桥道系整体性。