Dynamic performance of cable-stayed bridge tower with multi-stage pendulum mass damper under wind excitations——I:Theory

In this paper, wind-induced vibration control of a single column tower of a cable-stayed bridge with a multi- stage pendulum mass damper （MSPMD） is investigated. Special attention is given to overcoming space limitations for installing the control device in the tower and the effect of varying natural frequency of the towers during construction. First, the finite element model of the bridge during its construction and the basic equation of motion of the MSPMD are introduced. The equation of motion of the bridge with the MSPMD under along-wind excitation is then established. Finally, a numerical simulation and parametric study are conducted to assess the effectiveness of the control system for reducing the wind-induced vibration of the bridge towers during construction. The numerical simulation results show that the MSPMD is practical and effective for reducing the along-wind response of the single column tower, can be installed in a small area of the tower, and complies with the time-variant characteristics of the bridge during its entire construction stage.

Dynamic performance of cable-stayed bridge tower with multi-stage pendulum mass damper under wind excitations—Ⅱ: Experiment

The possibility of using a multi-stage pendulum mass damper （MSPMD） to control wind-induced vibration of a single column tower of a cable-stayed bridge during construction was studied theoretically in part I of this work. In this paper, the performance of the MSPMD for reducing bridge tower vibration is studied experimentally. A MSPMD model and a tower model of the bridge with geometry scaling of 1：100 were designed and manufactured. Calibration of the MSPMD model with different wire lengths is conducted to verify the analytical model of the damper. A series of tests for the uncontrolled freestanding tower, tower with cables, and tower with MSPMD model are then performed under harmonic and white noise excitations. The experimental results show that the responses of the tower model significantly decrease with the installation of the MSPMD model, which demonstrates the effectiveness of the M SPMD to mitigate the vibration of the bridge tower.

Aerodynamic problems of cable-stayed bridges spanning over one thousand meters

The elongating of cable-stayed bridge brings a series of aerodynamic problems. First of all,geometric nonlinear effect of extreme long cable is much more significant for cable-stayed bridge spanning over one thousand meters. Lateral static wind load will generate additional displacement of long cables,which causes the decrease of supporting rigidity of the whole bridge and the change of dynamic properties. Wind load,being the controlling load in the design of cable-stayed bridge,is a critical problem and needs to be solved. Meanwhile,research on suitable system between pylon and deck indicates fixed-fixed connection system is an effective way for improvement performance of cable-stayed bridges under longitudinal wind load. In order to obtain aerodynamic parameters of cable-stayed bridge spanning over one thousand meters,identification method for flutter derivatives of full bridge aero-elastic model is developed in this paper. Furthermore,vortex induced vibration and Reynolds number effect are detailed discussed.

Application of Wireless Monitoring System to Structural Health Monitoring of Long-Spanned Cable-Stayed Bridge

The remote monitoring system applied to the construction control and health monitoring of the Nanjing Third Yangtze River Bridge is introduced. The System makes it possible to get the structure capabilities and environmental parameters of the bridge at the predetermined moment. It sends the collected data over a long distance to an assigned position for display and analysis. The related methods and working condition of the wireless monitoring system are discussed. The measured data during 48 h are employed to determine the feasibility for the closure of the bridge.

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。

独柱型钢索塔施工阶段稳定性分析

为探明并验证斜拉桥独柱型钢索塔在施工阶段的结构稳定及极限承载性能,指导设计和施工,以上坝夹江大桥钢索塔为工程背景,基于有限元方法,研究主桥在施工阶段的弹性与弹塑性稳定性能。采用杆系模型对结构整体稳定进行分析,采用多尺度模型对结构局部稳定进行分析并验证整体稳定,对裸塔工况、最大双悬臂工况和最大单悬臂工况进行分析。通过弹性稳定分析得到结构主要失稳模态,通过弹塑性稳定分析,得到结构塑性铰连续形成历程,明确结构极限承载力以及破坏位置。结果表明:对比分析恒载和风荷载对独柱型钢索塔稳定性的影响程度,表明恒载是决定稳定系数的最主要因素,风荷载对钢索塔施工阶段弹性稳定系数影响很小,对弹塑性稳定系数影响较大;随着施工进展,结构整体的弹性稳定性和弹塑性稳定性逐渐下降,弹性稳定系数由18.5降至16.3,弹塑性稳定系数由3.03降至2.57;独柱型钢索塔的最终破坏形态为主塔中下塔柱区域范围大面积达到屈服强度,形成塑性铰,索塔的承载能力急剧下降,结构已失去承载能力,可能破坏的位置为中下塔柱位置;本研究独柱型钢索塔在施工阶段的弹性稳定系数最小为16.34,弹塑性稳定系数最小为2.57,均满足稳定性要求。

天水市藉口镇藉河大桥总体设计

天水市藉口镇藉河大桥主桥采用独塔双索面斜拉桥,边跨45 m+84m,主跨155 m,主塔采用钢筋混凝土钻石形塔,主梁采用预应力混凝土边纵梁,该桥采用塔、梁、墩固结体系,辅助墩及过渡墩处设置减隔震型抗震支座.阐述了该桥总体设计时在孔跨布置、主梁、主塔、斜拉索、基础等方面的尺寸确定.对高烈度地区独塔斜拉桥的设计提供了宝贵的工程经验.

某空间螺旋塔斜拉桥合理结构体系研究

某斜拉桥方案采用反对称螺旋形桥塔,空间四索面,造型较为新颖。由于桥梁结构较为复杂,为选用适宜的结构体系,基于桥梁结构的受力形态,在综合比较了漂浮体系、半漂浮体系、半固结体系的优劣后,确定半漂浮体系为最佳方案,并进一步讨论了地震作用下该桥合理的约束体系。这一流程对解决类似复杂结构桥梁合理结构体系的问题有一定参考价值。

上海祁连山路跨蕰藻浜大桥总体设计

祁连山路跨蕰藻浜大桥位于上海市宝山区,连接普陀区、宝山区的现状断头路,跨越Ⅲ级航道蕰藻浜。祁连山路跨蕰藻浜大桥主桥采用独塔双索面混合梁斜拉桥,跨径布置为(65+132)m,塔梁固结、塔墩分离结构体系,主梁采用钢-混凝土混合梁,主塔采用帆形塔,造型优美。现重点介绍祁连山路跨蕰藻浜大桥的跨径拟定、总体布置、结构体系、构造设计、成桥索力确定原则等。

钢结构斜塔斜拉桥创新设计与结构力学行为

斜塔斜拉桥因其造型优美、视觉效果优良等特点常应用于市政桥梁中。以成都天府国际空港新城北部北一线道路工程上的跨绛溪河钢结构斜塔斜拉桥为工程背景,该桥具有桥面较宽、单根背索、桥塔空间异形程度大等特点。基于此,为便于人车通行及结构布置,采用超宽渐变桥面,受超宽渐变桥面影响,所有主次横梁按均不等长设计;桥塔单侧设置1根背索,在塔顶和背索下锚处分散锚固。桥塔为空间异形结构,桥塔采用八边形断面形式,朝主跨的一个面设置凹槽造型,横向整体内倾12°,顺桥向为无规则弧形,为优化桥塔受力,在桥塔顶部节点设置4道桥塔系梁;鉴于该桥结构受力的复杂性,考虑几何非线性,基于有限元软件建立三维空间有限元模型,对最不利荷载下结构力学行为进行分析,分析表明:该桥强度、刚度和拉索疲劳等均满足要求;其中受力最不利点位于背索梁端锚固处,建议对此处进行加强优化设计。

海洋环境纤腰独柱式异形混凝土索塔施工技术

黄茅海跨海通道2座斜拉桥的5座主塔均采用纤腰独柱式异形混凝土索塔,造型优美、结构简洁。结构及施工环境复杂,面临着截面变化剧烈,模板及爬架设计困难;钢筋数量多,高空绑扎效率低安全风险高,保护层厚度控制难度大,影响海洋环境下混凝土耐久性;C55混凝土水泥用量多、水化热大,8cm保护层素混凝土开裂风险高等一系列施工难题。通过采用参数化模板设计、数控机床雕刻加工造型箱模板;钢筋分块部品施工工艺;优化配合比,掺加粘度改性剂,在保护层范围内增设玄武岩纤维等一系列施工措施,解决了相关技术难题,确保了施工质量,提高了施工效率,降低了安全风险,快速优质地完成了异形混凝土索塔的建造,为类似项目的施工提供了借鉴。

Seismic experimental study on a concrete pylon from a typical medium span cable-stayed bridge

According to the current seismic design codes of bridges in China, cable-stayed bridges have been usually required to remain elastic even subjected to strong earthquakes. However, the possibilities of pylon plastic behavior were revealed in recent earthquake damages. The lack of due diligence in the nonlinear seismic behavior of the pylon has caused a blurry understanding about the seismic performance of such widely built though less strong earthquake experienced structures. In light of this point, a 1/20 scaled concrete pylon model which from a typical medium span cable-stayed bridge was designed and tested on the shaking table longitudinally. The dynamic response and seismic behavior of the pylon were measured, evaluated and compared to reveal its vulnerable parts and nonlinear seismic performance. The results show that most parts of the concrete pylon remain elastic even under very strong excitations, which means a sufficient safety margin for current pylon longitudinal design. The most vulnerable parts of the pylon appeared first at the pylon bottom region, cracks opening and closing at the pylon bottom were observed during the test, and then extended to the lower column and middle column around the lower strut.

超宽幅主梁扭背索独塔斜拉桥总体设计

厦漳同城大道沙洲岛特大桥西溪主桥采用(88+200)m扭背索独塔斜拉桥,塔墩梁固结体系。主梁采用钢-混混合梁,其中主跨为整幅钢箱梁,梁宽47 m;边跨为预应力混凝土箱梁,梁宽51 m;钢-混结合面位于主跨距桥塔理论跨径线15 m处。桥塔采用独柱式钢筋混凝土斜塔,总高134.6 m,桥塔向边跨倾斜8°,其下布置整体式承台,钻孔桩群桩基础。斜拉索采用标准抗拉强度1670 MPa平行钢丝拉索,边跨斜拉索为双索面空间扭背索,主跨斜拉索为准单索面。针对超宽桥面,采用空间梁格法分析剪力滞的影响,将混凝土梁纵腹板由6道增至8道。按3 m顺桥向标准间距设置钢箱梁实体式横隔板,可使该桥宽幅主梁偏载、扭转效应导致的应力增量控制在允许范围内。对塔墩梁结合部进行有限元精细化分析,针对应力集中情况,优化局部构造和配筋设计,经计算,优化后结构受力满足设计要求。

空间异形独塔斜拉桥结构设计研究

柳州白沙大桥主桥为2×200 m独塔双索面钢箱梁斜拉桥,采用塔梁固结体系。桥塔为空间异形门形钢结构桥塔,由单箱矩形截面沿空间曲线扭曲而成;桥塔和斜拉索在主梁上、下游侧均反对称布置。采用MIDAS Civil软件建立主桥结构空间杆系有限元模型进行结构静力分析,通过调整塔柱中轴线线形优化桥塔结构内力,拟合出合理的塔柱中轴线方程;调整主梁高度为4.0 m和尾索靠边支点布置来提高桥梁结构刚度。在2根塔柱与主梁之间分别设置大横梁形成塔梁固结体系限制结构扭转,在梁端设置剪力卡榫抵抗横向水平反力,计入约束扭转效应情况下主梁和塔柱均满足强度及稳定要求。

大跨度高低塔公铁平层合建斜拉桥结构体系研究

甬舟铁路富翅门公铁两用跨海大桥采用主跨388 m高低塔公铁平层挑臂式钢箱梁斜拉桥,为世界上最大跨度的高低塔公铁平层合建斜拉桥。为研究适用于大跨度高低塔公铁平层合建斜拉桥最优结构体系,结合富翅门公铁大桥结构不对称的特点,对5种不同类型半飘浮体系、塔梁约束体系进行比选研究。通过对5种约束体系在静、动力荷载作用下的桥塔弯矩、桥塔位移、主梁位移对比分析,推荐采用高塔侧设置固定支座、矮塔侧采用活动支座的约束体系,该体系抵抗纵向荷载能力强、释放体系温度变形差,与常用的半漂浮体系相比,在静、动力荷载作用下桥梁总荷载效应小,具有良好的静动力性能,其中静力作用下两桥塔塔底总弯矩降低15%,两侧梁端总位移降低51%,两塔顶位移减少29%;动力作用下两桥塔塔底总弯矩相当,两侧梁端总位移降低76%。

聊城跨徒骇河莲花型单塔大跨斜拉桥结构设计

聊城兴华路跨徒骇河桥采用100 m+100 m独塔钢箱梁斜拉桥,该桥主塔整体造型采用莲花状结构,由2个主塔柱和1个副塔柱组成,主、副塔柱之间采用空间索面拉索相连,桥塔中轴线为椭圆,主塔和副塔分别高52.211 m、47.65 m,主、副塔柱轴线夹角30°;主梁采用钢箱梁,双箱单室截面,梁宽40 m,中线处梁高3 m;斜拉索为扇形布置的空间双索面,采用标准强度1770 MPa的平行钢丝斜拉索,全桥共72根斜拉索,斜拉索梁端锚固采用钢锚箱,钢锚箱焊接在主梁钢箱梁边箱室外侧;塔座、承台及桩基础采用混凝土结构,大桥共设置34根φ1.8 m的钻孔灌注桩,桩长70 m。莲花造型独塔斜拉桥的造型优美,创意独特,在满足结构各项受力性能要求的同时,很好地体现了聊城莲湖水利风景区的特色文化,使景区成为建筑艺术和谐交融的典范。

贵州凯峡河特大桥总体设计

贵州凯峡河特大桥为(180+230)m不对称半飘浮体系独塔结合梁斜拉桥,桥梁依次跨越凯峡河河谷和U形溶蚀槽谷。主梁采用双边“上”字形钢主梁与混凝土桥面板组成的结合梁,全宽30 m,桥面板采用C55高性能混凝土。桥塔采用“人”字形结构,塔高117 m。斜拉索采用环氧喷涂钢绞线成品索,按空间双索面扇形布置,单个索面布置18对,全桥共72根斜拉索。索塔锚固采用钢锚梁;索梁锚固采用锚拉板,为适应空间索面斜拉索锚固,锚拉板与钢主梁腹板采用小角度弯折焊接。桥塔采用爬模法施工,钢主梁采用桥面吊机悬拼。分别采用有限元软件MIDAS Civil和MIDAS FEA对斜拉桥进行总体和局部计算,结果表明该桥各项指标均满足规范要求。

公铁平层桥梁桥塔遮风效应风洞试验研究

车辆经过桥塔区域时,由于桥塔的遮风效应,其气动荷载会产生突变,且公铁平层桥梁的桥塔由于纵向尺度较大,车辆经过桥塔区域时气动荷载的变化更加剧烈.为明确某公铁平层桥梁上车辆在桥塔区域的气动特性,制作了1/20大比例尺的风洞试验模型;基于优化后的测试系统,测试了车辆通过公铁平层宽幅桥梁桥塔时的气动荷载,研究了车道位置、车辆类型以及桥塔外形对通过桥塔车辆的气动特性的影响.结果表明:越靠近桥塔车道上的车辆,经过桥塔时的横向力系数、摇头力矩系数的突变量更大,正向升力也越大,因而更容易发生侧滑与侧偏;车长对车辆通过桥塔区域的性能有显著影响,长度较小的车辆具有更大的横向力系数突变量,长度较长的车辆具有更大的倾覆力矩系数、摇头力矩系数及点头力矩系数突变量;与矩形截面桥塔相比,带倒角的桥塔使得厢式货车的横向力突变量减小了43.7%,使集装箱车的横向力系数突变量减小了25.8%,且使集装箱车的摇头力矩系数突变量减小了29.2%.

大跨度铁路单索面预应力混凝土斜拉桥设计关键技术及创新——以隆叙铁路沱江特大桥主桥设计为例

隆叙铁路沱江特大桥是隆叙铁路的控制性工程,为满足行洪、通航及一跨跨越珍稀、特有鱼类国家级自然保护区需求,结合本线新建单线预留双线条件的情况,采用主跨292 m单索面矮塔斜拉桥结构形式。为避免长期偏载,预留线二期恒载同步实施。通过对单箱三室截面、单箱双室贯通锚固截面、单箱单室大隔板截面、W形截面进行比较,优选传力路径直接、受力合理、施工方便的W形截面。针对变梁高时连续内腹板构造复杂、不便于施工的特点,在传统W形截面基础上提出纵向间隔布置预应力混凝土斜杆的W形截面主梁结构形式。通过对钢斜杆及预应力混凝土斜杆两种方案对比,分析斜杆内的预应力钢筋可主动承受拉索竖向分力、预压应力可有效避免较大变形和顶板开裂的特点。梁部采用挂篮悬臂浇筑施工。根据拉索布置及受力需要,结合泸州地方经济文化特色,提出束腰酒尊造型的桥塔结构。下部结构采用双薄壁墩、钻孔灌注桩基础,根据防洪、通航及两个主墩均衡受力的需求,对主墩岸坡进行刷坡防护。

单主缆悬索桥A形桥塔创新设计

柳州双拥大桥为国内首座大跨地锚式单主缆悬索桥,创新性地采用了独特的非相似等腰三角形截面所形成的A形钢塔。对该桥塔结构构造和受力行为进行的系统研究表明:该桥塔结构形式的景观效果和受力性能良好;塔底采用承压板-拉杆形式的钢混连接结构具有受力明确、施工便利的优点,塔顶需重点解决不同于双缆悬索桥的索鞍巨大竖向力向2个塔柱有效传递的构造问题。