高架简支梁桥非线性碰撞地震反应分析

本文首先简要分析了碰撞引起的建筑物破坏的现象，并对碰撞研究取得的成果、进展作了阐述、本文还对非线性碰撞单元（gap元）的力学特性进行了分析，最后利用NASTRAN大型通用结构分析程序就伸缩缝度、单（双）边碰撞对碰撞地震反应的影响作了定性分析，得出了许多有益的结论。     

地震作用下大型渡槽结构纵向碰撞非线性分析

本文依据建立的渡槽薄壁结构动力分析模型,利用非线性接触单元Kelvin碰撞模型,开展了渡槽结构纵向碰撞非线性地震响应分析。选择适合不同场地条件和不同峰值调幅的地震动输入,计算分析了南水北调某渡槽结构纵向碰撞地震响应。分析计算结果说明,伸缩缝间距大小对跨间碰撞效应影响很大;同时结构碰撞响应对输入地震动具有较强的频谱敏感性;经比较渡槽结构考虑碰撞与不考虑碰撞效应的地震反应,结果显示两者存在明显差异,说明开展大型渡槽结构非线性碰撞地震响应分析是很有必要的。     

双向地震作用下高铁FPS隔震简支梁桥纵向地震碰撞反应研究

为了准确分析FPS隔震桥梁的纵向地震碰撞反应,针对一典型3跨FPS隔震简支梁桥,建立了考虑FPS双向耦合效应和梁缝处三维碰撞效应的非线性动力计算模型,分析双向地震作用下FPS隔震简支梁桥纵向地震碰撞反应;研究支座半径和摩擦系数对简支梁桥纵向地震碰撞反应的影响规律。研究结果表明:横向地震作用会增大简支梁邻梁间纵向地震碰撞次数和碰撞力,降低墩底纵向剪力;为减小地震碰撞反应,设计时可适当增大支座半径和支座摩擦系数。     

双向地震作用下互通式斜交桥梁地震响应及碰撞效应分析

斜交桥梁由于其不规则的结构形式使其受力规律与规则桥梁相比具有特殊性和复杂性,在地震作用下梁体的平动与转动存在弯扭耦合效应,导致结构动力响应分析复杂。针对斜交桥梁的结构特点,建立包含桩土相互作用的三维有限元模型,在考虑水平双向地震作用下,采用反应谱法及时程分析法对京包高速公路某互通式斜交桥梁进行地震反应分析。结果表明:互通式简支斜交桥梁的地震响应受地震动输入方向的影响较大,在考虑碰撞效应后,碰撞涉及结构部位的地震位移显著增加,地震内力也出现较大差异,即说明在斜交桥梁抗震设计时有必要适当考虑地震动输入方向和梁端与墩台及相邻梁端的碰撞效应。     

连续梁桥减震、隔震体系非线性地震反应分析

本文采用微分型滞回恢复力模式代表桥梁减震,隔震支座的滞回,耗能特性,结合Ｗｉｌｓｏｎ－θ法和四阶Ｒｕｎｇｅ－Ｋｕｔｔａ法编制了桥梁减震,隔震体系非线性地震反应分析程序,并利用程序结合算例分析了减震,隔震支座对连续梁桥的减震效果。     

地震作用下隔震简支梁桥碰撞反应的振动台试验

由地震引发的碰撞是影响桥梁地震反应以及造成桥梁破坏的重要因素。本文对地震作用下隔震简支梁桥的碰撞反应进行了振动台试验。设计制作1个两跨简支的隔震梁桥模型,试验研究了梁间隙、邻梁质量比、隔震支座类型等参数对桥梁碰撞反应的影响。试验结果表明邻梁间隙、邻梁质量比、隔震支座类型等参数对桥梁的碰撞反应有着显著的影响。邻梁间隙越大,碰撞次数越少;邻梁质量比越大,撞击力越大。铅芯橡胶支座比板式橡胶支座耗能能力更强,可以有效降低邻梁之间的撞击力甚至避免碰撞发生。从而为桥梁防碰撞设计提供了可靠的试验依据。     

考虑梁体—挡块碰撞效应的桥梁地震响应数值计算

地震中桥梁梁体和挡块之间的碰撞是导致挡块破坏的直接因素.为定量研究由碰撞带来的横桥向地震响应的变化,采用Kelvin接触单元模型和SSH法数值计算方法,推导了考虑梁体—挡块碰撞效应的桥梁地震响应的数值计算方法和步骤,并用MATLAB编制了相应程序.通过对比计算结果和有关文献的试验数据可以看到,本文提出的计算方法计算效率高,结果准确.最后通过一个例子说明了本方法的实用性.     

城市桥梁地震碰撞反应研究与发展

地震时城市桥梁会因邻跨之间的碰撞而发生灾害.本文从桥梁碰撞的模拟模型、发生条件、影响因素、碰撞对桥梁抗震性能的影响以及防止碰撞的措施等方面,对国内外有关城市桥梁碰撞地震反应研究的成果进行了系统的总结和分析,得出以下结论：桥梁碰撞是多因素共同作用所导致的,并使得桥梁的地震反应更加复杂、呈现非线性;要准确评价桥梁地震碰撞反应需要建立更精确的模拟模型;选择合理的邻跨间距和支座宽度以及安装合适的消能减震装置,可有效地减小桥梁的地震碰撞反应.     

拱坝非线性地震反应分析

本文根据一致粘弹性模型的概念，引入应变率的影响，将混凝土静态William-Warnke三参数模型改造成一致粘塑性William-Warnke三参数本构模型，并用这个模型对某高拱坝进行了非线性地震响应分析，与线弹性模型和应变率无关的William-Warnke三参数模型的结果进行了比较，初步探讨了应变率对拱坝地震反应的影响。     

地震作用下曲线梁桥双向碰撞作用影响分析

碰撞作用直接影响到桥梁不同构件的地震响应,是桥梁抗震研究中一直关注的问题。针对地震作用下曲线梁桥因主梁面内转动而发生主梁与切向桥台和径向挡块碰撞的现象,以1座3跨预应力混凝土连续梁桥为例,采用非线性时程分析方法,对曲线连续梁桥的双向碰撞作用影响进行研究,并分析了不同减撞措施的效果。结果表明:考虑双向碰撞作用后,下部结构响应有明显增加,主梁转动现象变得复杂,曲线梁桥地震响应分析中应通过建立精细化模型来考虑主梁双向碰撞作用的影响;在切向桥台处设置限位拉锁装置能起到较好的减轻双向碰撞作用的影响,以及采用减隔震设计后,减撞效果更明显,桥梁抗震性能明显改善,但合理减撞措施设计参数应结合曲线梁桥约束体系及结构设计参数进行体系分析确定。     

地震作用下公路桥梁碰撞的半主动控制研究

针对地震作用下公路桥梁的碰撞问题,采用接触单元法模拟桥梁之间的碰撞作用,并在此基础上研究了采用磁流变阻尼器的公路桥梁碰撞的半主动控制方法。通过对某公路桥梁的数值模拟发现,地震作用下桥梁之间的相互碰撞,将大幅增加桥梁的绝对加速度响应。采用磁流变阻尼器的半主动控制系统能够较好地降低结构的地震响应和消除地震作用下的碰撞。     

Numerical failure analysis of a continuous reinforced concrete bridge under strong earthquakes using multi-scale models

Previous failure analyses of bridges typically focus on substructure failure or superstructure failure separately. However, in an actual bridge, the seismic induced substructure failure and superstructure failure may influence each other. Moreover, previous studies typically use simplified models to analyze the bridge failure; however, there are inherent defects in the calculation accuracy compared with using a detailed three-dimensional (3D) finite element (FE) model. Conversely, a detailed 3D FE model requires more computational costs, and a proper erosion criterion of the 3D elements is necessary. In this paper, a multi-scale FE model, including a corresponding erosion criterion, is proposed and validated that can significantly reduce computational costs with high precision by modelling a pseudo-dynamic test of an reinforced concrete (RC) pier. Numerical simulations of the seismic failures of a continuous RC bridge based on the multi-scale FE modeling method using LS-DYNA are performed. The nonlinear properties of the bridge, various connection strengths and bidirectional excitations are considered. The numerical results demonstrate that the failure of the connections will induce large pounding responses of the girders. The nonlinear deformation of the piers will aggravate the pounding damages. Furthermore, bidirectional earthquakes will induce eccentric poundings to the girders and different failure modes to the adjacent piers.     

Reduction of pounding effects in elevated bridges during earthquakes

Pounding of adjacent superstructure segments in elevated bridges during severe earthquakes can result in significant structural damage. The aim of this paper is to analyse several methods of reduction of the negative effects of collisions induced by the seismic wave propagation effect. The analysis is conducted on a detailed three‐dimensional structural component model of an isolated highway bridge. The results show that the influence of pounding on the structural response is significant in the longitudinal direction of the bridge and significantly depends on the gap size between superstructure segments. The smallest response can be obtained for very small gap sizes and for gap sizes large enough to prevent pounding. Further analysis indicates that the bridge behaviour can be effectively improved by placing hard rubber bumpers between segments and by stiff linking the segments one with another. The experimental results show that, for the practical application of such connectors, shock transmission units can be used. Copyright © 2000 John Wiley & Sons, Ltd.     

钢管拱桥在大地震作用下的非线性反应分析

钢管拱肋填充混凝土后，质量体系相对刚度体系的作用将大幅增加，特别是在大地震作用下的横向反应显著增大。拱肋内部不填充混凝土，能够减小横向地震作用，同时可以减轻下部结构的负担。因此，本文提出了圆形钢管拱肋的材料非线性性能的评价方法，并以上承式钢管拱桥为例，探讨了钢管拱桥在大地震作用下的非线性反应性能。     

强震下港珠澳连续梁隔震桥抗震性能研究

以实际港珠澳大跨度连续梁隔震桥为研究对象,采用纤维塑性铰单元模拟钢筋混凝土桥墩的非线性状态,建立其三维全桥有限元模型,对隔震及非隔震桥梁进行时程分析,采用桥墩曲率延性比和支座极限容许位移作为桥梁损伤破坏指标,定量评价隔震及非隔震桥梁在罕遇和极罕遇地震作用下的抗震性能,探讨隔震桥梁和非隔震桥梁的破坏模式;并研究材料非线性对桥梁结构地震响应的影响。研究结果表明：是否考虑材料非线性,对非隔震桥梁结构地震响应影响较大,对隔震桥梁影响较小;强震下隔震桥梁抗震性能明显高于非隔震桥梁,且破坏模式也不同于非隔震桥梁;隔震桥梁很好地保护桥墩构件,桥墩未发生任何损伤,而非隔震桥梁其桥墩在极罕遇地震作用时进入了严重破坏状态,且桥墩构件先于盆式支座发生损伤破坏。     

近场地震下简支梁桥搭接长度需求分析

随着交通网络向偏远地区辐射,桥梁结构会不可避免的出现靠近断层的情况,受到近断层地震动的影响显著。为了研究近场地震作用下简支梁桥的搭接长度需求,基于ANSYS平台建立了简支梁桥的弹塑性分析模型。通过动力响应分析、弹塑性分析和抗剪能力分析,探讨了近场地震动的脉冲效应对简支梁桥搭接长度的影响。研究表明：近场地震动的脉冲效应放大了结构的地震响应,脉冲型地震和非脉冲地震作用时的最大墩梁相对位移分别为115.1 cm和41.5 cm;两类地震作用时的最大剪力分别为1 892.5 kN和1737.8 kN,最大剪力剪切强度比为0.82;当PGA≥0.4 g时,脉冲型地震作用下桥墩底部塑性铰区的最大转角超过极限转角,桥墩发生破坏,而非脉冲型地震PGA=1.0 g时的塑性铰转角小于极限转角;当PGA=1.0 g时,塑性铰破坏前墩梁相对位移为37 cm,占规范搭接长度的41.8%,近场地震作用下简支梁桥的搭接长度需求满足规范要求。     

Linking of adjacent three-storey buildings for mitigation of structural pounding during earthquakes

The reports after major earthquakes indicate that the earthquake-induced pounding between insufficiently separated buildings may lead to significant damage or even total collapse of structures. An intensive study has recently been carried out on mitigation of pounding hazards so as to minimize the structural damages or prevent collisions at all. The aim of this paper is to investigate the effectiveness of the method when two adjacent three-storey buildings with different (substantially different) dynamic properties are connected at each storey level by link elements (springs, dashpots or viscoelastic elements). The results of the study indicate that connecting the structures by additional link elements can be very beneficial for the lighter and more flexible building. The largest decrease in the response of the structure has been obtained for links with large stiffness or damping values, which stands for the case when two buildings are fully connected and vibrate in-phase. Moreover, by comparing the effectiveness of different types of link elements, it has been confirmed that the use of viscoelastic elements reduces the peak displacement of the structure at lower stiffness and damping values comparing to the case when spring and dashpot elements are applied alone. On the other hand, the results of the study demonstrate that applying the additional link elements does not really change the response of the heavier and stiffer building. The final conclusion of the study indicates that linking two buildings allows us to reduce the in-between gap size substantially while structural pounding can be still prevented.     

A lagrange multiplier solution method for pounding of buildings during earthquakes

An effective solution method for studying the pounding response of two or more adjacent buildings during earthquakes is presented. The method is based on the Lagrange multiplier approach by which the geometric compatibility conditions due to contact are enforced. The energy and momentum balance criteria for the contacting bodies are satisfied according to the laws of impact with proper post-impact conditions, which can also take into account local energy absorption phenomena during impact. A solution scheme is proposed which can be incorporated easily into existing computer programs for static and dynamic analysis of structures. The applicability of the algorithm is illustrated in a number of selected sample problems and the correlation of numerical results to analytical solutions, whenever possible, is very satisfactory.     

大跨度斜拉桥地震响应非线性时程分析

以有限元分析理论为基础,结合某大跨度斜拉桥工程实例,利用ANSYS软件建立有限元模型,通过修正后的El Centro波分别考虑横向、竖向及纵向输入,采用时程分析方法对其进行地震反应分析.计算分析表明:考虑几何非线性后,结构的内力和位移响应明显增大,且对主梁和索塔内力与位移的影响程度及规律也不尽相同,须区别对待分析.同时表明该桥抗震性能良好,地震荷载不控制设计.由此得出结论,对于斜拉桥这类柔性体系, 不可忽视结构几何非线性的影响.     

基于碰撞调谐质量阻尼器的矮塔斜拉桥减震研究

以一座矮塔斜拉桥为研究对象,分析碰撞调谐质量阻尼器对于该结构的抑震效果。首先介绍了新型碰撞调谐质量阻尼器（Pounding Tuned Mass Damper,PTMD）的减震机理及基于接触单元的非线性碰撞力模型;之后,通过ANSYS软件中的APDL语言实现了PTMD减震系统的时域分析方法,并通过三条实际地震记录验证了PTMD的抑震效果。数值分析结果表明:（1）传统调谐质量阻尼器（tuned mass damper,TMD）及新型PTMD对于矮塔斜拉桥的位移、加速度及塔身弯矩响应均有较好的抑制效果;（2）PTMD相比传统TMD多了一种碰撞耗能模式,其减震效果略高于传统TMD。