Internal Force Distribution in Steel-Concrete Composite Structure for Pylon of Cable-Stayed Bridge

Adopting a steel-anchor beam and steel corbel composite structure in the anchor zone on pylon is one of the key techniques for the design of Jintang bridge, a cable-stayed bridge in Zhoushan, China. In order to ensure the safety of the steel-concrete composite structure, a stud connector model for the joint section was put forward. Experiments were conducted to obtain the relation between load and slip of specimen, the failure pattern of stud connector, the yield bearing capacity and ultimate bearing capacity of a single stud, etc. The whole process of the structural behavior of the specimen was comprehensively analyzed. The features of the internal force distribution in the steel-concrete composite structure and the strain distribution of stud connector under different loads were emphatically studied. The test results show that the stud connector is applicable for the steel-concrete composite structure for pylon of Jintang bridge. The stud has a good ductility performance and a obvious yield process before its destruction. The stud connector basically works in a state of elasticity under a load less than the yield load.

Evaluation of Current Design Practices on Estimation of Axial Capacity of Concrete Encased Steel Composite Stub Columns： A Review

This paper presents the design assessment of concrete encased I-sections composite column based approaches given in Eurocode, ACI Code, BS Code and AISC-LRFD. This study includes comparison of various design parameters and evaluation of design strength based on the procedures predicted in the various codes of practices. A practical example has been assumed and calculation has been shown to evaluate their potentiality in understanding in predicting the potentiality of various procedures. The obtained results based on the methods varies widely, because of the different design considerations adopted by the different codes. As such, they have hardly considered the effect of confinement of the concrete due to the presence of longitudinal reinforcements as well as lateral ties. The study has attempted to throw light on critical review and their potentiality in assessing the strength of such concrete encased composite column under purely axial loads.

Static behavior of semi-rigid thin-walled steel-concrete composite beam-to-column joints with bolted partial-depth flush end plate:experimental study

A new type of semi-rigid thin-walled steel-concrete composite beam-to-column joint has been proposed in this paper.Five semi-rigid composite beam-to-column joint specimens subjected to hogging moments under monotonic loading were tested to study the static behavior of this new type of joint.The main variable parameters for the five joint specimens were the longitudinal reinforcement ratio and the joint type.The experimental results designated that the magnitude of extension of the longitudinal reinforcement is the most important factor that influenced the moment-rotation characteristic of the new type of joint.The concrete slabs could resist 3.8%-19.1% of the total shear load applied to the cross-sections near the beam-to-column connection.The edge stiffened elements,such as the flange of the lipped I-section thin-walled steel beam,were capable of having considerable inelastic deformation capacity although they had comparatively large width-to-thickness ratios.The shear failure of the concrete cantilever edge strip must be taken into account in practical design because it has significant influence on the anchorage of the longitudinal reinforcement in the new type of external joints.

Identification of Connection Flexibility Effects Based on Load Testing of a Steel-Concrete Bridge

In the case of composite girders, an effective cooperation of both parts of the section is influenced by deformability of connectors. Limited flexural stiffness of welded studs, used commonly in bridge structures, does not provide full interaction of a steel beam and a concrete slab. This changes strain distribution in cross-sections of a composite girder and results in redistribution of internal forces in steel and concrete element. In the paper partial interaction index defined on the basis of a neutral axis position, which can be used for verification of steel-concrete interaction in real bridge structures rather than in specimens is proposed. The range of the index value changes, obtained during load testing of a typical steel-concrete composite beam bridge, is presented. The investigation was carried out on a motorway viaduct, consisting of two parallel structures. During the testing values of strains in girders under static and quasi-static loads were measured. The readings from the gauges were used to determine the index, characterizing composite action of the girders. Results of bridge testing under movable load, changing position along the bridge span is presented and obtained in-situ influence functions of strains and index values are commented in the paper.

Technological development and engineering applications of novel steel-concrete composite structures

In view of China's development trend of green building and building industrialization,based on the emerging requirements of the structural engineering community,the development and proposition of novel resourcesaving high-performance steel-concrete composite structural systems with adequate safety and durability has become a kernel development trend in structural engineering.This paper provides a state of the art review of China's cutting-edge research and technologies in steel-concrete composite structures in recent years,including the building engineering,the bridge engineering and the special engineering.This paper summarizes the technical principles and applications of the long-span bi-directional composite structures,the long-span composite transfer structures,the comprehensive crack control technique based on uplift-restricted and slip-permitted (URSP)connectors,the steel plate concrete composite (SPCC)strengthen technique,and the innovative composite joints.By improving and revising traditional structure types, the comprehensive superiority of steel-concrete composite structures is well elicited.The research results also indicate that the high-performance steel-concrete composite structures have a promising popularizing prospect in the future.

装配式轻钢框架-轻钢骨架轻混凝土墙板结构抗震性能

为研究装配式轻钢框架-轻钢骨架轻混凝土墙板结构抗震性能,对1个足尺轻钢框架结构试件和3个足尺轻钢框架-轻钢骨架轻混凝土墙板结构试件进行了低周反复荷载下的抗震性能试验及理论分析,试件变量包括:2种装配构造,即内嵌式装配墙板、外贴式装配墙板;2种轻钢骨架轻混凝土墙板,即框架式轻钢骨架轻混凝土墙板、桁架式轻钢骨架轻混凝土墙板。研究了各试件的破坏特征和损伤演化过程,分析了结构滞回特性、承载力、变形能力、刚度退化、耗能性能和应变。结果表明:装配式轻钢框架-轻钢骨架轻混凝土墙板结构共同工作性能良好,其水平承载力相比轻钢框架提高了204.7%~210.4%,抗侧刚度提高了257.3%~512.5%,结构变形及耗能能力有显著提高;内嵌墙板的自攻钉连接构造以及外贴墙板的螺栓连接构造传力性能可靠,结构具备2道抗震防线的受力特征;基于简化塑性分析模型以及拉压杆软化桁架模型,对试件承载力进行了计算,计算结果与试验符合较好。

常泰长江大桥组合索塔锚固结构钢-混传剪构造足尺模型试验研究

常泰长江大桥索塔锚固结构采用钢箱-核芯混凝土组合结构,为研究该新型组合索塔锚固结构钢-混传剪构造的受力特性,进行钢-混传剪构造足尺模型试验研究。制作2个锚固结构足尺节段试验模型,通过压剪试验研究锚固结构的荷载~滑移曲线及应力、应变分布等受力特性,并通过有限元模型分析锚固结构的传力机理和各组件的内力分配比例,推导剪力钉剪力计算方法。结果表明:在2.14倍单索最大索力荷载作用下,锚固结构保持弹性状态,钢壁板未产生明显滑移,钢-混界面最大滑移不超过0.25 mm,该锚固结构中钢-混传剪构造至少具有2.14倍的安全系数;荷载作用下,剪力钉剪力从上至下逐渐增大,锚腹板附近底部3排剪力钉剪力较大,钢-混传剪构造至少存在剪力钉和界面摩擦力2种传剪机制,钢-混传剪构造的承载能力显著提高;钢-混传剪构造受力过程分为粘结力传力阶段和局部滑移阶段,剪力钉剪力分布不仅与沿剪切方向长度分布有关,也与荷载的大小线性相关。

钢-UHPC结合段PBL连接件和钢梁端面承压联合作用研究

钢-混结合段作为钢梁和混凝土连接为整体的核心部件,传力构件的受力性能对钢-混凝土结合段至关重要。为提高结合段的力学性能,进行了仅有钢梁端面承压、PBL连接件和两者联合作用3组推出试验。结果表明:3组试件最终破坏裂缝分布均为钢梁端面侧“八”字形分布;钢梁端面组(D组)试件破坏模式主要为UHPC的开裂破坏而失效,PBL连接件组(P组)和联合作用组(PD组)试件主要是贯穿钢筋的剪切破坏而失效;3组试件的荷载-滑移曲线均包含弹性、裂缝开展和屈服3个阶段,由于贯穿钢筋和UHPC榫具有抑制裂缝开展和提高试件延性的作用,P组和PD组试件裂缝开展阶段较D组更短,屈服阶段更长,延性更好。对荷载-滑移曲线进行拟合,提出了钢梁端面承压和PBL连接件承载力随滑移量变化的计算公式。引入滞后滑移差Δs_(j),当Δs_(j)=0~0.67 mm时,联合作用计算结果偏于安全。计算得到钢梁端面承压传力比例约为43%,PBL连接件传力比例约为57%,两者传力效果基本相当。利用UHPC作为外包混凝土时,建议采用承载能力更高的贯穿钢筋,以充分发挥UHPC的高强性能,从而提高结合段的承载能力。

装配式型钢混凝土叠合框架梁连接节点构造设置与安全分析

住房和城乡建设部印发《“十四五”建筑业发展规划》提出大力发展装配式建筑、推动生产和施工智能化升级的主要任务。而国内目前采用的预制叠合框架梁存在着跨度大自重大吊装成本高、预制梁柱节点位置易发生钢筋碰撞吊装定位难度大等问题,限制了装配式建筑结构的发展。结合实际工程项目,提出一种新型的装配式型钢混凝土叠合框架梁,并对该叠合梁的构造设置、连接方式及安全性进行分析,从而为装配式框架结构、框架—剪力墙结构等装配式建筑中框架梁的深化设计提供一种新的拆分方案。

大跨度钢-混结合梁悬索桥涡激振动控制指标体系研究

为保证已建桥梁发生涡激振动后桥梁结构的安全以及桥上行车和行人安全,提出综合考虑人员舒适性、结构受力和停车线形三方面的大跨度钢-混结合梁悬索桥涡激振动控制指标体系。该体系包含9项指标,分别为驾乘人员舒适度、驾乘人员晕动症、行人舒适度(狄克曼指标)、加劲梁强度、加劲梁应力、加劲梁挠度、桥面纵坡、竖曲线半径和停车视距。以武汉鹦鹉洲长江大桥为背景,分别计算了“限速”和“封桥”2个交通管制措施下9项指标对应的涡激振动振幅限值。在此基础上,将9项指标对应的涡激振动振幅限值的最小值作为涡激振动限值建议取值。结果表明:当该桥发生低阶竖弯涡激振动(VS1、VAS1)时,涡激振动的控制因素为加劲梁挠度指标;当大桥发生VAS2模态的竖弯涡激振动时,涡激振动由驾乘人员晕动症指标和行人舒适度指标共同控制;当大桥发生高阶竖弯涡激振动(VAS3、VAS4)时,涡激振动由行人舒适度指标控制。涡激振动控制指标体系及限值标准的计算框架可适用于不同桥型涡激振动限值的计算。

波纹钢-混凝土复合结构高温压弯性态研究

波纹钢-混凝土复合结构因其强度较高且施工高效已逐渐应用于隧道支护中,但波纹钢板由于无混凝土的保护,在高温下性能劣化严重。依托云南省普洱市高山寨隧道,利用ABAQUS软件建立有限元模型进行数值模拟分析,研究波纹钢-混凝土复合结构在不同温度和不同偏心距正负弯矩作用下的多工况高温压弯性态。研究结果表明,随着温度的升高,波纹钢-混凝土复合结构中和轴逐渐上移,初始抗弯刚度和极限荷载逐渐下降;当温度>500℃时,结构性能降低幅度最大,宜将500℃作为结构重点关注温度。

深中通道钢壳-混凝土组合沉管浇筑变形研究

深中通道沉管管节采用钢壳-混凝土组合结构形式,通过向空钢壳浇筑混凝土预制而成。为评估沉管管节施工后的整体变形,建立了热-结构顺序耦合的分析框架,基于ANSYS APDL及UFPs二次开发模块,分别建立了考虑水化度、日照辐射、大气温度变化的精细温度场模型和考虑混凝土硬化及收缩特性的结构分析模型。通过对足尺管节的温度及应变模拟结果与监测数据的对比,验证了有限元模型的可靠性。在此基础上,分析了日照辐射、大气温度变化等对于管节温度场的影响,同时分析了管节的整体变形模式,以及温度效应、混凝土收缩及自重三种因素对管节整体横向、纵向及竖向变形的影响。结果表明:管节施工过程的温度场表现为时变和空间分布的特征,格仓边部温度受外界气温变化和日照辐射的影响存在周期性波动,而格仓中部温度峰值主要受混凝土自身水化放热特性的控制;管节最终表现为顶板横向及纵向内收,竖向下挠,底板横向及竖向变形不显著;太阳辐射对于结构温度场影响较日气温变化更显著,建议在混凝土温度峰值预测中予以考虑,而日气温变化可采用日平均气温值予以简化;温度效应及材料收缩对管节横向及纵向整体变形影响显著,自重因素导致的变形在横向及纵向的比例为44.3%、11.7%,而在竖向所占比例达92.5%,因而温度效应及材料收缩在管节横向及纵向变形分析中不可忽视;该分析方法可适用于大体积混凝土等结构的温度效应的预测和评估。

铁尾矿基多固废混凝土抗压性能及微观结构分析

针对铁尾矿堆存困难、综合利用率低和活性低的问题,以铁尾矿钢渣脱硫灰为复合掺合料制备多固废混凝土。通过抗压性能测试,研究复合掺合料掺量、铁尾矿细度对混凝土抗压强度的影响,并利用压汞法(MIP)和背散射电子成像技术(BSE)探究混凝土的微观结构。结果表明:复合掺合料的掺入对混凝土早期抗压强度影响较大,掺量小于20%的混凝土28 d抗压强度与无掺合料组抗压强度基本持平,30%掺量的混凝土抗压强度随铁尾矿比表面积的增大而先增大后减小;掺入复合掺合料和减小铁尾矿细度能够改善混凝土孔结构和提高界面过渡区的密实度。

装配式带夹芯保温槽型玻璃钢-钢板-槽钢-混凝土组合剪力墙轴压性能研究

提出一种装配式带夹芯保温槽型玻璃钢-钢板-槽钢-混凝土组合剪力墙,设计3个具有不同配筋形式和混凝土种类的墙板试件进行轴心受压试验,获得墙板在轴压作用下的破坏模式、荷载-位移曲线、荷载-应变曲线、承载力储备系数、延性系数、材料利用率等性能指标。通过ABAQUS有限元分析软件对墙板进行参数化分析,研究内嵌钢板强度和厚度对其轴压性能的影响。结果表明,墙板具有良好的承载力储备能力和延性性能;混凝土中掺入1%体积比的钢纤维可显著提高墙板内混凝土的抗拉性能,使混凝土强度得到更加充分的利用,布置钢筋可以显著提高墙板延性;墙板的承载力和延性随内嵌钢板厚度和强度的增加而增大,强度为Q355、厚度为4、6mm时,墙板材料利用率更高。提出适用于该类墙板的轴压承载力设计公式,考虑钢板屈曲和截面组合效应的墙板轴心受压承载力设计公式计算结果较精确。

书夹型钢-混组合结构在桥梁加宽中的应用研究

为避免桥梁加宽时下部结构拓宽,减少新旧桥面纵向裂缝及铺装层损伤,提出一种以钢结构立柱及护栏、书夹式钢板、高强度螺栓为主要构件,超高性能混凝土(UHPC)为铺装层的书夹型钢-混组合结构进行桥梁加宽。为评估该组合结构在运营条件下的安全性,以厦门官浔溪大桥加宽工程为背景,通过实桥现场静载试验研究水平荷载作用下书夹型钢-混组合结构的力学性能,并与数值仿真结果进行对比,验证试验结果的可靠性。结果表明:实测结果与数值仿真结果吻合良好;书夹型钢-混组合结构关键部位荷载~位移曲线、荷载~应力曲线呈线性变化,钢结构最大拉应力约为材料屈服强度的75%,整体结构处于弹性工作阶段;螺栓预紧力有效减少了高强度螺栓的直剪作用,降低了剪切疲劳破坏风险;采用书夹型钢-混组合结构进行桥梁加宽可有效避免下部结构拓宽,改善新旧桥面纵向裂缝及铺装层损伤,具有较好的加宽效果。

东津黄河大桥主桥总体设计

东津黄河大桥主桥为(50+180+420+180+50) m双塔钢-混组合梁斜拉桥,采用半飘浮结构体系;主梁采用宽34 m的双边钢箱-混凝土桥面板组合梁;桥塔采用无下横梁的A形桥塔+分离式承台,承台间设横向系梁,塔梁交接处设置牛腿支承主梁,塔柱底部设置破冰体;基础采用?2.0 m钻孔灌注桩,最大桩长117 m;斜拉索采用标准抗拉强度1 860 MPa平行钢丝拉索,按空间双索面扇形布置,塔端采用钢锚梁+混凝土齿块锚固,梁端采用钢锚箱锚固于主梁边钢箱外腹板。计算结果表明,该桥结构静、动力性能良好,各项指标满足规范要求。

马鞍山长江公铁大桥主航道桥桥塔设计

马鞍山长江公铁大桥主航道桥为双主跨1 120 m的三塔钢桁梁斜拉桥,桥梁跨度大、受力复杂,桥塔设计要求高。桥塔设计过程中对边中塔比例、结构形式、结构尺寸等进行比选分析,基于提高结构整体刚度、优化中塔受力和控制中塔基础工程规模的考虑,最终确定采用中塔塔顶高程高于边塔,边塔、中塔均为钢-混组合结构的方案。边塔塔高308 m和306 m,采用平面A形塔;中塔塔高345 m,采用空间A形塔。桥塔分为上塔柱、中塔柱、下塔柱3个区段。上塔柱为钢结构,采用钢锚箱式索塔锚固结构。中、上塔柱交界处设钢-混结合段,结合段外壁板布置PBL剪力键和剪力钉,结合段内设有一圈锚杆,钢塔柱竖向压应力通过结合段的承压板和剪力连接件传递至混凝土塔柱,拉应力通过锚杆传递至混凝土塔柱。中、下塔柱为混凝土结构,五边形截面。中、下塔柱交界位置设置横梁,边塔布置1道下横梁,中塔布置2道下横梁,中塔2道下横梁之间通过3道系梁连接。横梁均为预应力混凝土结构,系梁为钢筋混凝土结构。经计算,桥塔受力满足设计要求,桥塔各构件受力明确、安全合理。

U型Twin-PBL剪力键极限承载力的数值分析

根据端部承压混凝土可提高Twin-PBL剪力键承载能力的特点,提出一种新型的可用于装配式钢混组合结构的间断式U型Twin-PBL剪力键。通过3组推出试验试件的非线性数值模拟分析,研究了这种新型剪力键的极限承载特点和承载力。结果表明:U型Twin-PBL剪力键极限承载能力较普通承压型Twin-PBL剪力键有显著提高,且提高主要来源于端部混凝土承压面积增大,所以混凝土强度的提高对该剪力键承载能力影响明显,而孔中混凝土榫和贯穿钢筋两部分对承载力贡献无明显变化,故而通过修正端承压混凝土面积得到了这种剪力键承载力计算公式。研究结果为装配式钢-混凝土组合梁桥的间断式剪力键提供了新的思路。

SRPE管-混凝土-钢双壁空心短柱轴压性能试验研究

针对西部盐渍土地区钢筋混凝土桥柱的腐蚀问题,提出“SRPE管-混凝土-钢双壁空心柱”。为研究其轴心受压力学性能,设计制作了6根SRPE管-混凝土-钢双壁空心短柱并进行轴压试验,获得了试件的破坏形态和荷载-位移曲线,进而分析了SRPE管压力等级、空心率和钢管径厚比对试件轴心受压力学性能的影响规律。研究结果表明:试件的破坏形态为中下部剪切破坏;试件极限承载力随SRPE管压力等级提高而增大,随空心率和钢管径厚比增大而减小,且空心率影响大于钢管径厚比。最后给出了SRPE管-混凝土-钢双壁空心短柱的轴心受压承载力计算式,计算结果与试验值吻合良好。

先简支后桥面板连续体系桥面板抗裂性能研究

先简支后桥面板连续体系是一种新型钢混组合结构,在该体系的中支点处设置一定长度的钢梁-混凝土桥面板分离段,可以改善桥面板负弯矩区的受力状态。目前对于该体系桥面板负弯矩区这一薄弱环节的试验研究尚属空白。本研究首先根据实际一座先简支后桥面板连续的钢混组合梁桥,设计制作了两跨1/4比例的缩尺模型,并通过安装、拆除带套筒剪力钉对中支点处的分离段长度进行调节。然后通过在两跨桥面上模拟单轮重轴荷载进行逐点加载试验,研究了分离段长度对桥面板受力状态和抗裂性能的影响。最后对原桥的抗裂性能进行了分析。结果表明,中支点处设置分离段的先简支后桥面板连续体系可显著改善结构的抗裂性能。本研究有助于推广先简支后桥面板连续体系在钢混组合结构中的应用、推动桥梁结构预制装配技术的发展。