Seismic performance of cable-sliding friction bearing system for isolated bridges

During past strong earthquakes, highway bridges have sustained severe damage or even collapse due to excessive displacements and/or very large lateral forces. For commonly used isolation bearings with a pure friction sliding surface, seismic forces may be reduced but displacements are often unconstrained. In this paper, an alternative seismic bearing system, called the cable-sliding friction bearing system, is developed by integrating seismic isolation devices with displacement restrainers consisting of cables attached to the upper and lower plates of the bearing. Restoring forces are provided to limit the displacements of the sliding component. Design parameters including the length and stiffness of the cables, friction coefficient, strength of the shear bolt in a fixed-type bearing, and movements under earthquake excitations are discussed. Laboratory testing of a prototype bearing subjected to vertical loads and quasi-static cyclic lateral loads, and corresponding numerical finite element simulation analysis, were carried out. It is shown that the numerical simulation shows good agreement with the experimental force-displacement hysteretic response, indicating the viability of the new bearing system. In addition, practical application of this bearing system to a multi-span bridge in China and its design advantages are discussed.

Modeling of cable vibration effects of cable-stayed bridges

The analysis of dynamic responses of cable-stayed bridges subjected to wind and earthquake loads generally considers only the motions of the bridge deck and pylons.The influence of the stay cable vibration on the responses of the bridge is either ignored or considered by approximate procedures.The transverse vibration of the stay cables,which can be significant in some cases,are usually neglected in previous research.In the present study,a new three-node cable element has been developed to model the transverse motions of the cables.The interactions between the cable behavior and the other parts of the bridge superstructure are considered by the concept of dynamic stiffness.The nonlinear effect of the cable caused by its self-weight is included in the formulation.Numerical examples are presented to demonstrate the accuracy and efficiency of the proposed model. The impact of cable vibration behavior on the dynamic characteristics of cable-stayed bridges is discussed.

Cable flexural rigidity influence on suspension bridges static properties

In order to figure out the cable flexural rigidity influence on suspension bridges,a contrast model experiment is made:a chain cable model with no flexural rigidity and a wire cable model with some flexural rigidity.And then,four finite element models of a same long-span suspension bridge with different cable element are set up to be analyzed.Both experimental and numerical simulation results show that,with the increase of the span and the decrease of sag-span ratio,the influence of the cable flexural rigidity is significant.The difference of nodes displacement reaches more than 10 cm in construction analysis,which will bring some trouble to the construction.And the difference of the maximum section edge normal stress may reach 15%,which may have an adverse impact onto the bridge.Therefore,considering the cable flexural rigidity is necessary on some analysis of suspension bridges.

Developments and Prospects of Long-Span High-Speed Railway Bridge Technologies in China

With the rapid developments of the high-speed railway in China, a great number of long-span bridges have been constructed in order to cross rivers and gorges. At present, the longest main span of a constructed high-speed railway bridge is only 630 m. The main span of Hutong Yangtze River Bridge and of Wufengshan Yangtze River Bridge, which are under construction, will be much longer, at 1092 m each. In order to overcome the technical issues that originate from the extremely large dead loading and the relatively small structural stiffness of long-span high-speed railway bridges, many new technologies in bridge construction, design, materials, and so forth have been developed. This paper carefully reviews progress in the construction technologies of multi-function combined bridges in China, including com- bined highway and railway bridges and multi-track railway bridges. Innovations and practices regarding new types of bridge and composite bridge structures, such as bridges with three cable planes and three main trusses, inclined main trusses, slab-truss composite sections, and steel-concrete composite sections, are introduced. In addition, investigations into high-performance materials and integral fabrication and erection techniques for long-span railway bridges are summarized. At the end of the paper, prospects for the future development of long-span high-speed railwav bridges are provided.

Advanced aerostatic analysis of long-span suspension bridges

As the span length of suspension bridges increases, the diameter of cables and thus the wind load acting on them, the nonlinear wind-structure interaction and the wind speed spatial non-uniformity all increase consequently, which may have unnegligible influence on the aerostatic behavior of long-span suspension bridges. In this work, a method of advanced aerostatic analysis is presented firstly by considering the geometric nonlinearity, the nonlinear wind-structures and wind speed spatial non-uniformity. By taking the Runyang Bridge over the Yangtze River as example, effects of the nonlinear wind-structttre interaction, wind speed spatial non-uniformity, and the cable＇s wind load on the aerostatic behavior of the bridge are investigated analytically. The results showed that these factors all have important influence on the aerostatic behavior, and should be considered in the aerostatic analysis of long and particularly super long-span suspension bridges.

罕遇地震下高速铁路大跨矮塔斜拉桥减隔震性能研究

为研究不同减隔震装置对高速铁路大跨矮塔斜拉桥的减隔震机理,以某(90+180+90)m矮塔斜拉桥为研究背景,基于非线性时程分析建立有限元模型,研究摩擦摆支座、黏滞阻尼器和减隔震组合装置的减震效果及桥梁的抗震性能。结果表明:罕遇地震作用下,全桥主塔处采用摩擦摆支座和黏滞阻尼器的组合装置可以有效解决抗震问题,优化后选取摩擦系数为0.06、曲率半径为2 m的摩擦摆支座和阻尼系数为12000 kN·(m·s^(-1))-α、阻尼指数α为0.8的黏滞阻尼器;相比于单独使用摩擦摆支座或黏滞阻尼器,减隔震组合装置可大幅度减小全桥各关键截面的内力、桥墩位移及梁端转角,显著提升桥梁的抗震性能,剪力和弯矩的减震率分别达70.85%和76.94%,桥墩墩顶位移减震率达76.08%;各关键截面安全系数均大于1,结构均处于弹性范围,满足桥梁抗震性能的要求。

外露型钢锚箱组合索塔锚固区水平传力机理

为揭示外露型钢锚箱组合索塔锚固区水平传力机理,基于弹性介质层法推导钢锚箱壁板-混凝土塔壁结合面滑移的理论计算式,进而得到连接件剪力流、钢与混凝土构件轴力的计算方法。通过平截面假定、理论计算式与锚固区节段模型试验结果的比较,验证理论计算式合理性并进行参数化影响分析。研究结果表明:顺桥向预应力和水平索力同时作用时,钢混结合面最大相对滑移0.055 mm,焊钉连接件最大剪力15.99 kN,钢锚箱侧壁板受拉应力6.55 MPa,混凝土塔壁受压应力−1.07 MPa;钢锚箱侧壁板、混凝土塔壁承担顺桥向预应力的比例为10%和90%,水平索力的比例为26%和74%;锚固区水平传力机理受钢锚箱侧壁板厚度、混凝土塔壁厚度、结合面传力长度、连接件抗剪刚度与顺桥向预应力作用的影响很大。

高速铁路高低塔斜拉桥减隔震装置研究

通过分析各类减隔震装置对高速铁路高低塔混合梁斜拉桥的减隔震作用,从而选取合理减隔震装置。以阜淮(阜阳—淮北)新建高速铁路跨颍河主跨230 m的高低塔混合梁斜拉桥为研究对象,建立铅芯橡胶支座、摩擦摆式减隔震支座、黏滞阻尼器有限元模型,采用非线性时程分析法对塔底弯矩、梁端水平位移等目标函数进行地震响应分析。结果表明:采用铅芯橡胶支座,塔底弯矩降幅达到49.9%;采用摩擦摆减隔震支座,塔底弯矩降幅达到54.3%;采用黏滞阻尼器,塔底弯矩降幅达到62.0%。对于高速铁路高低塔混合梁斜拉桥而言,黏滞阻尼器减隔震装置更合理,并给出合适设计参数。

边墩约束对塔梁墩固结体系斜拉桥横桥向减震影响研究

为了解塔梁墩固结体系斜拉桥的横桥向地震响应并选取合理的抗震结构体系,以主跨305 m的湖南帅乡特大桥为背景,采用MIDAS Civil软件建立不同边墩约束方案(7种常规支座边墩约束方案、1种摩擦摆球型支座边墩约束方案)的桥梁三维有限元模型,分析不同边墩约束条件对塔梁墩固结体系斜拉桥塔底横桥向弯矩及主梁梁端横桥向位移的影响。结果表明:相较于采用常规支座边墩约束方案,采用摩擦摆球型支座边墩约束方案不仅可以减小塔梁墩固结体系斜拉桥在地震作用下的塔底横桥向弯矩,还可以将主梁梁端横桥向位移控制在较小的数值内,显著提高了塔梁墩固结体系斜拉桥横桥向抗震性能;E2地震作用下,地震引起的结构响应普遍比静力计算结果小,主墩、桥塔及边墩均处于弹性状态,抗震不控制设计。湖南帅乡特大桥最终采用设置摩擦摆球型支座的边墩约束方案。

济南大北环黄河特大桥总体设计

济南大北环黄河特大桥位于济南绕城高速二环线北环段,由主桥和引桥组成,全长5 830 m。主桥采用(50+350+350+50) m独塔自锚式悬索桥,桥塔为独柱混凝土结构,空间缆索布置,主梁采用双边钢箱梁,通过横梁连接;为提高主桥结构整体刚度,桥塔处采用X形横梁以满足顺桥向双排支座布置要求,并在主跨跨中设置1对辅助斜拉索;桥面板采用钢-UHPC组合桥面板;主缆通过散索鞍后保持竖向无转向,水平横桥向转向14.08°后锚固。主桥采用“先梁后缆”施工方案,钢梁采用支架拼装及顶推施工,塔柱采用爬模施工,塔梁施工完成后进行主缆及吊索架设。滩地引桥上部结构采用装配式预应力混凝土T梁;跨大堤桥及国道220跨线桥上部结构采用变截面现浇预应力混凝土连续梁;堤外引桥上部结构采用先张法预制预应力混凝土工字梁。

强震下斜拉桥支座碰撞分析

为了研究竖向地震动对斜拉桥支座碰撞的影响,基于OpenSees平台建立了精细化有限元模型,选取了3条具有代表性的地震波作为地震动输入,研究了强震下斜拉桥上部结构与支座的碰撞现象。研究发现,强震下斜拉桥主梁竖向最大位移可达0.7 m,支座碰撞力为成桥状态支座压力的2.3~4.0倍。过大的支座碰撞力会超过支座极限设计荷载,引起支座结构破坏甚至桥梁结构受损,在工程中应该予以预防。

在役高速公路大跨度斜拉桥荷载试验研究

淮安大桥为大跨度双索面斜拉桥,已服役18年,为掌握大桥当前结构状态和受力性能,对大桥进行荷载试验,针对主梁最大正负弯矩、主塔最大弯矩、主梁挠度、塔偏等设计加载工况。结果表明,淮安大桥测试截面的平均应变、挠度及塔顶偏位的校验系数均处在合理范围内,相对残余均小于20%,大桥处于弹性工作阶段,受力性能良好,满足设计荷载的正常使用要求。

某高速特大桥抗震设计方案对比分析

以某高速特大桥为分析对象,分别采用普通球型支座、普通球型支座+粘滞阻尼器(主墩)两种方案进行桥梁抗震比选分析,探究使用粘滞阻尼器后对双塔斜拉桥抗震性能的影响。计算结果表明:横波下普通支座的水平力最大值为20686 kN,各支座的横向水平力与其对应的竖向承载力之比分布在28%~86%范围内,纵向位移分布在255 mm~300 mm范围内。通过在主墩设置粘滞阻尼器,支座的纵向位移降至115 mm~148 mm范围,均小于150 mm,墩底剪力、墩底弯矩减少至原设计方案的26%,49%,支座位移和内力显著减小,提高了桥梁在纵波作用下的抗震性能,可以有效抑制结构的震动响应和形变,从而最大限度地削弱地震对桥梁结构造成的冲击损害,提升结构的整体抗震韧性。

斜拉桥大吨位支座更换施工及监控

某斜拉桥经过近16年的运营,主桥大吨位竖向支座出现了四氟滑板存在挤出、磨耗严重等情况,为防止支座病害影响斜拉桥结构,将主桥8个大吨位支座更换为具有较高耐磨性能的盆式支座。对支座更换设计进行仿真建模分析,提出了支座更换的控制性参数--顶升位移量及顶升力,采用PLC多点同步顶升设备进行桥梁支座更换,对关键截面的应力和位移进行全过程实时监控。工程实践证明,更换技术实施效果良好,支座更换前后,结构位移、应力实测结果与变化趋势均符合理论变化规律,且均控制在安全指标之内,为今后国内外大跨径斜拉桥更换大吨位支座提供有益参考。

西堠门公铁两用大桥岩锚锚碇承载特性研究

甬舟铁路西堠门公铁两用大桥主桥采用主跨1488 m斜拉-悬索协作体系桥,金塘岛侧采用岩锚锚碇。为研究该桥岩锚锚碇的承载特性,基于地质概化模型、岩体力学参数,构建岩锚锚碇结构与岩体互相作用的三维数值模型,分析预应力和主缆荷载作用下围岩变形特征与塑性区分布规律及超载作用下岩锚的破坏模式与围岩稳定安全系数。结果表明:按顺序施加预应力和主缆荷载后,岩体最大变形分别为2.75 mm、1.99 mm;施加预应力有利于减小岩锚锚碇系统的变形;在承受主缆荷载时岩锚锚碇系统工作性能良好,带动了较大范围的深层岩体参与承担主缆荷载;岩锚破坏模式是从后锚室上方破坏并向上部发展;初步判断岩锚围岩稳定安全系数为7.0;建议岩锚体上方不宜大范围削坡扰动岩体,并采取增加框架锚索、锚杆防护等加固措施。

斜拉-悬索协作体系桥过渡区斜拉索和吊索布置形式研究

针对斜拉-悬索协作体系桥过渡区斜拉索和吊索共用梁上锚点的传统布置时易出现端吊索疲劳、边跨主梁恒活载弯矩大等问题,提出过渡区斜拉索和吊索纵向交错的新型布置形式。以某主跨1488 m的公铁两用斜拉-悬索协作体系桥为背景,分析过渡区斜拉索和吊索采用传统布置形式与新型布置形式时主梁竖向位移、斜拉索索力、吊索索力、刚度过渡匀顺性、主梁与桥塔活载弯矩等方面的差异。结果表明:新型布置形式对结构竖向刚度的影响较小,但显著改善了斜拉索和吊索的受力状态,提高了承载效率,且解决了端吊索的疲劳问题,改善了主梁的匀顺性,减小了主梁和桥塔的活载弯矩。

G3铜陵长江公铁大桥江北侧锚碇复合型地下连续墙设计

G3铜陵长江公铁大桥主桥为主跨988 m的斜拉-悬索协作体系桥。江北侧锚碇设计时对沉井基础和地下连续墙基础进行比选,综合考虑开挖范围、工程造价、施工工期等,最终采用基底深置的地下连续墙基础,以下伏基岩弱胶结泥质砂岩作为基础持力层,基础高49.5 m,地下连续墙墙底嵌入中等胶结泥质砂岩,地下连续墙高55.5 m。为减小锚碇基础的开挖量,采用大悬臂外挑锚块结构结合CFG桩复合地基加固技术的新型复合型地下连续墙基础,地下连续墙基础直径缩小至60 m,节省了工程造价。锚碇基础施工中基坑分层开挖,同时进行内衬砌施工。采用PLAIXS 3D软件对锚碇施工阶段及运营阶段进行有限元模拟分析,基坑开挖时地下连续墙结构受力安全,锚碇基础地基承载力、地基沉降结果均满足规范要求。

大跨度悬索桥长索夹抗滑承载能力研究

通过建立索夹主缆系统接触摩擦精细化模型,分别研究在不同的索夹壁厚、索夹紧固螺栓间距以及接触摩擦系数的条件下,紧固作用下的主缆表面径向应力和切向应力分布情况,评估主缆因不同紧固条件对长索夹抗滑承载能力的影响。结果表明主缆表面应力沿环向分布很不均匀,靠近索夹开口位置附近主缆表面接触应力明显大于索夹靠近主缆天顶线的接触应力;索夹壁厚主要对索夹开口处以及索夹变截面处的主缆表面应力产生影响,索夹壁厚越大抗滑安全系数越小;接触面摩擦系数越大,索夹开口位置附近切向应力越大,而接触面径向应力整体越小,同时索夹轴向最大摩擦阻力也越大;索夹间距只影响主缆整体的应力大小,随索夹间距增大,索夹抗滑摩阻力也越大,增大螺栓间距有利于提高索夹的抗滑承载能力。

杭州市彭埠大桥主桥钢梁设计

杭州市彭埠大桥主桥为(73.4+122+4×240+122+73.4)m公轨两用多跨悬链形上加劲钢桁梁桥,采用双层桥面布置,上层通行双向8车道公路,下层通行双线地铁与两侧各5.5 m宽的慢行系统。主桥钢梁横向采用2片主桁,桁宽36.8 m,桁高12 m,节间长10、12 m,主桁钢梁节点为全焊接整体节点,采用两节间半桁片结构设计及拼装方案;上、下层桥面均采用正交异性钢桥面板,竖撑杆位置与上层公路桥面纵梁及下层轨道桥面边纵梁位置对应;为改善上、下层横梁受力,钢梁所有节点处均设置横向联结系;钢梁设置悬链形上加劲弦杆,杆件全高从1.2 m渐变为2.8 m。钢梁采用先架设平弦部分钢桁梁,再施工上加劲系统的总体顺序,平弦部分钢桁梁架设采取双向顶推施工。施工过程中钢梁最大顶推重量为22000 t,最大顶推长度为565 m,最大悬臂长度为80 m。采用MIDAS Civil软件对该桥运营阶段及施工阶段进行受力验算,结果表明该桥结构刚度较大,运营阶段及施工阶段钢梁受力满足规范要求。

坦桑尼亚坦桑蓝跨海大桥主桥合龙顺序研究

坦桑尼亚坦桑蓝跨海大桥主桥为(85+4×125+85)m五塔六跨矮塔斜拉桥,主梁为鱼腹式预应力混凝土等高箱梁,采用普通挂篮悬浇施工,设6个合龙口。为选择边跨、次边跨和中跨合理的合龙顺序,采用MIDAS Civil软件建立主桥不同合龙顺序有限元模型,分析合龙顺序对主梁恒载预拱度、应力、合龙阶段位移以及成桥索力的影响。结果表明:合龙顺序对主梁恒载预拱度影响较大,对主梁合龙阶段位移有一定影响,但对主梁应力、成桥索力影响较小,先边跨再次边跨最后中跨合龙的顺序为该桥最优合龙顺序。最终该桥采用了先边跨再次边跨最后中跨的顺序合龙,施工和成桥阶段全桥线形控制良好,结构受力安全。