Non-linear buffeting response analysis of long-span suspension bridges with central buckle

The rigid central buckle employed in the Runyang Suspension Bridge (RSB) was the first time it was used in a suspension bridge in China. By using a spectral representation method and FFT technique combined with measured data,a 3D fluctuating wind field considering the tower wind effect is simulated. A novel FE model for buffeting analysis is then presented,in which a specific user-defined Matrix27 element in ANSYS is employed to simulate the aeroelastic forces and its stiffness or damping matrices are parameterized by wind velocity and vibration frequency. A nonlinear time history analysis is carried out to study the influence of the rigid central buckle on the wind-induced buffeting response of a long-span suspension bridge. The results can be used as a reference for wind resistance design of long-span suspension bridges with a rigid central buckle in the future.

Influence of central buckle on suspension bridge dynamic characteristics and driving comfort

The central buckle, which is often used in a suspension bridge, can improve bridges' performance in the actual operation condition. The influence of the central buckle on natural vibration characteristics and bridge-deck driving comfort of a long-span suspension bridge is studied by using a case study of Siduhe Suspension Bridge in China. Based on the finite element software ANSYS and independently complied program, the influence of the central buckle on the structure force-applied characteristics of a long-span suspension bridge has been explored. The results show that the huge increases of natural frequencies can result in the presence of central buckles because of the increases of bending and torsional rigidities. The central buckle basically makes the stiffening girders and cables within the triangular area covered as a relatively approximate rigid area. Hence, the central buckle can reduce the torsional displacement of the main girder. However, the increases of bending and torsional rigidities have little influence on the impact factor, which is obtained by using vehicle-bridge coupled vibration analysis. This means that the central buckle has little effect on the comfort indices. In addition, it is found that the central buckle can enhance the bridge deck's driving stability due to the decrease of the torsional displacements of the main girder.

Buckling Analysis of TF Coil Inner Leg for Central Solenoidless Tokamak

The central post is one of the critical components for the low aspect ratio tokamak, which endures not only a tremendous ohmic heating because it carries a rather high current, but also a large neutron heating and irradiation owing to the plasma operation. The DS copper alloy Glidcop AL-25[8] was chosen as the conductor material for its adequate mechanical properties and physics properties. The central post has a cylindrical structure with lots of cooling channels. The length of the central post for the next generation of nuclear fusion spherical tokamaks will be more than 10 m or 20 m. The structural stability is very crucial. When the applied load is larger than the structure critical buckling load, the device will lose its stability and collapse. In order to calculate the critical buckling load, a 1/6-segment finite element model was used and the force acting on the central post was simulated. The results showed that the vertical compressive stresses mainly affect the stability of the central post. The linear buckling analysis results with finite element method based on small deformation theory were given in this paper. The relation curves and functions for buckling factor, depending on the different lengths and the radius of the central post, the diameter of cooling channel and the maximum allowable current density, were also shown.

开口断面钢-混结合梁悬索桥颤振特性及颤振形态研究

为准确评估开口断面双边箱钢-混结合梁悬索桥颤振性能和多模态参与效应,以典型的钢-混结合梁悬索桥——怀化洞庭溪沅水特大桥为背景,开展风洞模型试验及数值分析。制作加劲梁节段缩尺模型并进行风洞试验,测试原桥梁结构的颤振性能,分析调整阻尼比、采用气动措施及结构措施对结构颤振特性的影响,采用三维和二维两种颤振分析方法分析设置中央扣结构的颤振模态及多模态参与效应。结果表明:该钢-混结合梁悬索桥存在较明显的颤振起振点,且颤振是以扭转为主的弯扭耦合振动,同时其扭转和竖向振动存在较大的相位差(相差近180°);节段模型风洞试验与三维和二维颤振分析一致得到设置中央扣后,频率较高的正对称扭转模态先于反对称模态发生颤振,且三维与二维颤振分析结果相差不大。

随机车载激励下大跨度悬索桥中央扣振动控制研究

大跨度悬索桥车流荷载作用下振动响应明显,关键构件疲劳损坏直接影响结构服役状态及运营安全。为改善大跨度悬索桥结构振动响应,基于有限元模拟对柔性中央扣及刚性中央扣振动控制效应开展研究,分析了中央扣对结构模态特性的影响,并基于考虑参数相关性及车流参数聚类特征的随机车流模拟方法,分析了车流荷载下的中央扣振动控制效应及其对吊索钢丝寿命影响。研究结果表明:中央扣主要对悬索桥的反对称竖弯频率及一阶扭转频率存在影响,随着柔性中央扣数量的增加结构振动频率有所提升,刚性扣的提升效果与三柔性中央扣接近。车流作用下中央扣可显著减小梁端位移、梁端累计位移及缆梁相对位移,随柔性中央扣数目的增加,控制效率有所提升但提升效果逐渐减小。刚性中央扣对梁端位移及梁端累计位移的控制效果与三柔性扣索接近,其对缆梁相对位移的控制效果好于柔性中央扣。吊索钢丝的疲劳寿命与弯曲应力响应的变化趋势一致,长吊索整体弯曲应力水平相对较小,中央扣对其钢丝寿命影响不明显。短吊索钢丝疲劳寿命则大幅提升,但柔性中央扣数量的增加提升效果有限,刚性中央扣提升效果与三柔性扣索接近。

压载荷下Ⅰ-Ⅱ复合型中心裂纹板弹塑性屈曲载荷研究

为了研究含裂纹结构承载能力,采用有限元方法建立压载荷下Ⅰ-Ⅱ复合型中心裂纹板模型,计算裂纹板弹塑性屈曲载荷,讨论相对裂纹长度(a/w)、裂纹倾角(θ)、板宽(w)、板厚(t)、边界条件对弹塑性屈曲载荷及其变化规律的影响。对于上下夹持中心裂纹板,随着裂纹长度和裂纹倾角的增大,板宽越大,中心裂纹板屈曲载荷对裂纹越敏感,中心裂纹板承载能力受到裂纹长度和裂纹倾角的影响越明显。弹塑性屈曲载荷随着板厚的增大而增大,并且随着裂纹倾角的增大,板厚越大,屈曲载荷的下降程度越显著。上下简支中心裂纹板与上下夹持中心裂纹板的屈曲载荷变化规律基本一致,且上下夹持中心裂纹板的屈曲载荷显著大于上下简支中心裂纹板的屈曲载荷。给出不同边界条件下弹塑性屈曲载荷与相对裂纹长度、裂纹倾角的回归关系式。通过中心裂纹板弹塑性屈曲试验发现,采用压缩力学性能计算弹塑性屈曲载荷更接近试验结果,试验屈曲载荷的变化规律与有限元模拟计算结果一致。研究结果对含裂纹结构的承载能力评价具有参考价值。

大跨度悬索桥多对刚性中央扣受力性能研究

中央扣对改善大跨度悬索桥动力特性、短吊杆弯折、主梁纵向位移等具有显著作用,但现有文献少见对中央扣自身力学行为的研究。该文以中央扣为研究对象,通过力学方法推导了中央扣侧移刚度的计算公式,通过敏感性分析确认了杆身倾角α以及杆身轴向刚度j是影响中央扣侧移刚度的主要因素;对设置多对刚性中央扣的情况进行了研究,因主缆与中央扣杆身轴向刚度相差不大,主缆对多对中央扣协调受力影响较大,中央扣与主缆组成串、并联弹簧体系,受力分配更加复杂,可通过调整杆身倾角及杆身轴向刚度,设置具有不同侧移刚度的多对中央扣以实现协调受力。

中央扣索对悬索桥静动力特性的影响分析

中央扣索是提高悬索桥刚度的有效措施之一,也是悬索桥的重要构件,因此有必要研究中央扣索对悬索桥振动特性、内力、变形的影响。该文以某单跨钢桁梁悬索桥为例,建立2个模型进行对比分析计算。通过分析计算得出,中央扣索增加主桁与主缆、吊索之间的相对纵向刚度,从而使该桥纵飘频率明显增大;在公路-Ⅰ级荷载作用下,主桁沿顺桥向的变形有一定程度的减小,并引起中央扣索区域内弦杆内力和吊索索力突变;对其他截面内力、节点变形基本无影响。

环湖绿道红星坪悬索桥总体设计

红星坪悬索桥桥梁总长232 m,主桥为双塔单跨悬索桥,主跨为222 m,垂跨比1/10.2;桥面宽度6 m,净宽4.8 m。索塔采用钢筋混凝土塔柱;主缆及抗风缆锚碇采用重力锚;加劲梁采用分离式钢箱梁,上、下游设置抗风缆。通过详细阐述人行悬索桥的总体设计要点,结构设计关键节点,为后续类似项目提供指导。

大跨度缆索承重桥梁主梁梁端位移特性研究

为研究不同体系大跨度缆索承重桥梁主梁梁端位移特性,以主跨988 m的斜拉-悬索协作体系桥——G3铜陵长江公铁大桥主桥为背景,构建相同跨径斜拉桥方案及悬索桥方案,采用有限元软件建立模型计算3种方案在运营阶段的梁端位移,并对梁端位移影响因素进行分析。结果表明:斜拉-悬索协作体系桥方案的梁端位移最小;对斜拉桥方案施加与斜拉-悬索协作体系桥主缆对桥塔纵向约束刚度相同刚度的塔顶纵向弹性约束,对悬索桥方案施加与斜拉-悬索协作体系桥斜拉索对主梁纵向约束刚度相同刚度的塔梁纵向弹性连接或在跨中增设中央扣,可大幅减小斜拉桥方案和悬索桥方案的梁端位移,其中纵向荷载(纵向有车风荷载和制动力荷载)引起的梁端位移大幅减小,活载引起的梁端位移也有一定程度的减小。斜拉-悬索协作体系桥方案存在主缆-桥塔-斜拉索-主梁的纵向约束体系,相对单纯的斜拉桥方案与悬索桥方案,对抵抗纵向荷载有较大的优势,因此其梁端位移小于单纯的斜拉桥方案和悬索桥方案。

基于连续支承压杆模型的轴心受压柱局部屈曲分析

轴心受压柱局部屈曲分析,一般根据薄板理论建立板件屈曲微分方程,构造满足边界条件的位移场,获得屈曲临界载荷解析解,不仅推导繁琐且不便直观地揭示受压板件屈曲特征及控制参数。本文建立单位宽度受压板条的连续支承压杆模型,将二维板件屈曲问题转化为学生较熟悉的一维压杆屈曲分析。基于连续支承压杆临界载荷的解析解,方便识别典型非加载边约束下板件屈曲半波数。本文旨在深化理解受压板件屈曲性能。

竖向荷载作用下悬索桥纵向变位特征与机理

为揭示竖向荷载作用下悬索桥纵向变位特征与机理,以主缆变形理论为基础研究了其竖向荷载下的变位特征,并得出了其竖向及纵向位移解析解;在此基础上,分析了竖向荷载作用下传统悬索桥和设有中央扣悬索桥的纵向变位特征及加劲梁纵向位移,揭示了中央扣纵向约束机制,并分别推导了加劲梁在竖向荷载下的纵向位移计算公式;最后,通过算例分析验证所提位移计算公式计算精度.结果表明:由于主缆的几何非线性特征,竖向位移与纵向位移相互耦合,在非对称竖向荷载作用下,主缆发生非同步纵向位移,而加劲梁主要以类似“摆锤体”发生刚体的纵向位移;跨中处主缆、加劲梁及中央扣因中央扣的存在形成一个“刚域”区,从而导致加劲梁纵向位移减小;所提计算方法与有限元数值解法在不同竖向荷载工况下吻合良好.

Accurate stress analysis on rigid central buckle of long-span suspension bridges based on submodel method

Runyang Suspension Bridge (RSB) with the main span of 1490 m is the longest bridge in China and the third longest one in the world. In this bridge the rigid central buckle is employed for the first time in the mid-span of the suspension bridge in China. For such a super-long-span bridge, the traditional finite element (FE) modeling technique and stress analysis methods obviously cannot satisfy the needs of conducting accurate stress analysis on the central buckle. In this paper, the submodel method is in- troduced and for the first time used in analyzing the stresses of the central buckle. After an accurate FE submodel of the central buckle was specially established according to the analysis results from the whole FE model, the connection technique between the two-scale FE models was realized and the ac- curate stresses of the central buckle under various vehicle load cases were then conducted based on the submodel method. The calculation results were testified to be accurate and reliable by the field measurements, which show the efficiency and reliability of the submodel method on analyzing the mechanical condition of the central buckle of long-span suspension bridges. Finally, the working be- havior and mechanical characteristics of the central buckle of the RSB under vehicle loads were ana- lyzed based on the calculation and measurement results. The results obtained in this paper can provide theoretic references for analyzing and designing the rigid central buckle in long-span suspension bridges in future.

列车移动荷载作用下大跨度悬索桥纵向位移控制研究

为有效控制列车移动荷载作用下大跨度悬索桥梁端产生的纵向位移,以某大跨度铁路悬索桥为背景,采用非线性动力时程分析法,考虑几何非线性和边界非线性,研究在货运列车移动荷载作用下,改变结构体系和约束体系对悬索桥纵向位移的控制效果。结果表明:结构体系方面,设置中央扣和水平拉索均可增大悬索桥结构纵向刚度,显著减小梁端纵向位移;设置中央扣还可减小缆、梁端纵向位移差,对纵向位移控制效果更优。约束体系方面,随着粘滞阻尼器速度指数减小,梁端纵向位移峰值逐渐减小;磁流变阻尼器对梁端纵向位移控制效果有限。采用2种阻尼器组合约束可控制列车过桥纵向位移同时不显著增加缆、梁端纵向位移差。

中央扣对大跨悬索桥动力特性的影响

基于ANSYS软件建立了润扬长江公路大桥南汊悬索桥的三维有限元计算模型,并采用子空间迭代法对其进行了自振特性分析,研究了刚性中央扣的多精度模拟技术及其对大跨度悬索桥动力特性的影响。研究结果表明,中央扣的不同精度模拟对该桥动力特性的影响很小;与跨中短吊索相比,中央扣的设置使得结构刚度有所增加,相应的各阶频率增大,但各类振型受影响的程度不同,其中以缆索振动为主的频率增加最为明显。研究结果为该桥的健康监测提供了必要的信息和研究基础。

中央扣对三塔悬索桥地震反应的影响

针对三塔悬索泰州长江大桥这一特殊桥型,基于Abaqus台建立了该桥的空间动力有限元模型并进行非线性动力分析.研究了地震作用下,缆梁间刚性中央扣对三塔悬索桥塔梁位移、塔柱内力以及塔梁间弹性拉索的影响.研究结果表明:中央扣对三塔悬索桥动力特性有不可忽视的影响;由于中央扣增强了缆梁间相互作用,在地震作用下,中塔横向位移与加劲梁跨中竖向位移均有所增加,中塔柱纵桥向剪力有所减小;中央扣限制了加劲梁纵向位移并减小了加劲梁对中塔下横梁的作用,但边塔柱底扭矩有所增加.

中央扣对不同悬吊结构体系悬索桥的影响分析

为研究中央扣对不同悬吊结构体系悬索桥受力的影响,文章以西堠门大桥为背景,采用西南交通大学编制的桥梁非线性计算软件BNLAS建立了计算模型,模型中主缆的跨度为578m+1650m+465m。通过比较加劲梁不同的支承形式分析中央扣对悬索桥受力的影响。

中央扣对大跨度悬索桥地震响应影响及机理研究

为研究不同形式中央扣对悬索桥地震响应影响规律及机理,本文结合某三跨铁路悬索桥,基于ANSYS有限元分析软件建立三维空间有限元分析模型,对比分析不同中央扣设置形式对桥梁自振特性的影响。通过非线性时程分析,对在塔梁位置设置纵向黏滞液体阻尼器前后不同形式中央扣对悬索桥地震响应的影响规律进行研究。通过响应控制振型的研究,揭示中央扣对各响应产生不同影响的机理。研究结果表明:仅通过自振特性分析不能直接得到准确的中央扣对桥梁地震响应影响规律;不同中央扣设置形式下,主梁竖向位移及各项内力响应均大幅增加,塔底弯矩、剪力有所减小,以刚性中央扣为最优;考虑阻尼器后,不同形式中央扣对大跨度悬索桥地震响应的影响与无阻尼器情况基本一致,其原因是设置阻尼器并未改变桥梁各响应的控制振型。

车辆激励下中央扣对悬索桥梁端位移的影响

为研究中央扣对悬索桥梁端位移的影响,以洞庭湖二桥为工程背景,考虑结构几何非线性效应,建立相应的全桥空间有限元动力模型.基于有限元模型,考虑多种行车工况,研究了中央扣对该桥动力特性及在车辆激励下对梁端位移的影响.结果表明:中央扣能显著提高悬索桥的整体纵向刚度,改变悬索桥的纵飘模态特性.在车辆激励下,设置中央扣明显减小了加劲梁的纵向振幅,提高了加劲梁的振动频率,导致梁端累加位移值增大.双向行驶的车辆越多,增设中央扣后梁端位移峰值减小得越明显.不同类型的中央扣造成悬索桥对应的共振车速和主梁的动力响应各不相同.行车工况下,不同类型中央扣对梁端位移的控制效果各有差别.