随机地震动场激励下拱坝多点输入的抗震可靠度分析

本文首次将空间随机地震场输入用于拱坝随机振动分析之中，与拱坝三维动力学有限元法结合，完成了三维拱坝在空间随机地震动场作用下的随机振动分析方法及算法的研究，另外考虑动力和静力的叠加，提出了三维空间随机地震动场的拱坝抗震可靠度分析方法，最后编制了相应的程序，对小湾拱坝进行了抗震可靠度分析，并与随机变量的结果进行了比较。     

结构多维地震作用研究综述及展望（Ⅰ）—地震动输入

综术了结构多分量地震作用研究的发展概况，在第（Ⅰ）部分中，主要综述了多分量地震动输入的有关问题，分别从多分量地震动的转动分量，随机模型及相关性的研究方向进行了讨论。在第（Ⅱ）部分中，主要综述了结构在多分量地震作用下的反应分析方法，包括多分量抗震分析的反应主普法，时程法和随机方法，最后讨论了多分量地震作用研究中存在的问题，对今后的研究方向提出了展望。     

基于小波变换的层间隔震结构地震响应分析

利用小波多分辨率分析将地震动加速度分解为多频段小波分量,并运用复模态方法推导其计算层间隔震体系在地震作用下的动力响应公式,讨论各频段地震信号及结构响应的能量分配。同时利用小波时频工具分析地震动能量在时频域内的分布对层间隔震结构响应的影响,进而为考察地震动非平稳性对层间隔震结构非线性分析的影响提供方法。利用小波分析的以上优势,对一典型层间隔震结构分别进行弹性和弹塑性分析,结果表明弹性体系在地震作用下的响应可由该地震波各小波分量的响应叠加而得,地震动能量在时间上的集中会对层间隔震结构响应产生不利影响。     

多点输入随机地震动拱坝-地基体系反应分析

采用等效地基集总参数方法,推导了拱坝－地基体系的简化多点随机输入分析模型,对拱坝－地基动力相互作用体系在多点随机输入地震波作用下的随机响应到进行了分析,并对地基柔度及地震动空间相干性损失对拱坝随机响应的影响进行了讨论。     

考虑场地类别和断层距的地震动及结构响应参数相关性分析

为了研究场地条件和断层距对地震动参数及其与结构响应参数相关性的影响,本文基于NGA数据库中5 266条水平分量地震动记录,采用皮尔森相关系数,分析了不同场地条件和断层距下地震动参数之间的相关性及其与结构响应参数的关系。结果表明,场地条件和断层距对绝大部分地震动参数相关性会产生明显影响,但存在一些参数的相关性几乎不受场地条件和断层距的影响;以四层钢筋混凝土框架结构为例,发现在不同场地条件和断层距下,结构响应参数与地震动参数的相关性变化明显,这表明在研究结构响应与地震动参数相关性时需要考虑场地条件与断层距的影响。     

基于不同设计反应谱的溪洛渡拱坝动力响应分析

合理的设计反应谱是保证高拱坝动力分析和安全评价结果可靠的前提。为研究不同反应谱时程对拱坝非线性响应的影响,分别基于GB 51247—2018《水工建筑物抗震设计标准》设计反应谱、DL 5073—2000《水工建筑物抗震设计规范》设计反应谱、以及溪洛渡场地相关反应谱,拟合出地震动时程,采用溪洛渡拱坝-库水-地基系统非线性损伤开裂模型进行拱坝的非线性地震响应分析。结果表明：反应谱的选择对溪洛渡拱坝地震响应影响显著,相比于2000年标准反应谱,2018年标准反应谱使溪洛渡拱坝坝顶最大动相对位移增加、坝顶上游面横缝开度增大、孔口和坝踵位置损伤加深。并且,2018年标准下的坝体动力响应整体高于基于场地谱的计算结果,而2000年规范下的坝体动力响应低于场地谱的计算结果,说明2000年规范理应更新,2018年标准更符合当下的抗震设计需求。     

高压断路器隔震体系抗震可靠度分析

给出了基于随机地震动模型的高压断路器抗震可靠性分析方法。通过建立高压断路器及其隔震体系的有限元计算模型，分析了在断路器底部瓷套管根部加设叠层橡胶垫后的动力性能，分析中利用随机地震动模型，充分考虑地震动的随机作用，给出了四类场地土条件下结构的地震响应均值和标准差；利用一次二阶矩理论计算得到高压断路器的可靠度，给出了各场地土条件下的震害率曲线。结果表明不同场地土条件下隔震垫的减震效果有所差异。     

地震作用下输电塔线耦联体系导线减震作用研究

为了研究输电线在地震动过程中质量效应和非线性振动效应对塔体减震的作用,以皖电东送淮南-上海输变电工程为背景,设计了单塔模型、单塔悬挂等效集中质量块模型和塔线体系模型三种缩尺试验模型并进行了振动台试验。通过分析试验结果我们认为:考虑导线的质量效应后,塔体在地震动作用下的结构动力响应有所降低,并且输电线质量效应对于垂直线路方向的减震效能明显优于顺线路方向;考虑输电线的非线性振动效应之后,塔体在地震动作用下的结构动力响应在质量效应减震的基础上有了进一步的减小,并且地震动幅值越大,输电线非线性振动效应导致的塔体减震效果也愈明显。     

远场地震动长周期特性对基础隔震结构地震响应影响研究

与普通强地震动相比,长周期地震动的低频分量丰富,对长周期结构影响显著。隔震结构作为一类具有较长自振周期的结构,其在长周期地震动作用下的动力行为值得研究。选取远场长周期地震记录和远场普通地震记录作为外部激励,以某基础隔震结构作为研究对象,研究了远场地震记录的长周期特性,及其对隔震层和上部结构地震响应的影响。研究结果表明:远场地震动长周期特性对结构地震响应的影响显著,远场长周期地震记录下结构的地震响应明显大于远场普通地震记录,在隔震结构设计中应考虑其不利影响;地震动功率谱与结构地震响应之间存在明显联系,应进行深入研究。研究结果可为长周期地震动作用下隔震结构的抗震设计提供参考。     

地震动竖向分量对铁路房屋的地震响应性能影响

为了提高铁路房屋的抗震能力,分析地震动竖向分量对铁路房屋的地震响应性能,提出基于荷载—变形关系联合评估的地震动竖向分量对铁路房屋的地震响应评估模型。构建地震动竖向分量的力学响应评估模型,识别铁路房屋的地震屈服响应参数,采用荷载—变形关系和极限荷载结合的方法进行铁路房屋的地震屈服响应应力评估,分析地震动竖向分量对铁路房屋的响应。建立动量平衡方程和弯矩平衡方程,构建铁路房屋的地震响应的三阶段荷载—变形模式,实现地震动竖向分量对铁路房屋的地震响应性能评估模型的优化设计。测试结果表明,采用该模型能有效分析地震动竖向分量对铁路房屋的地震响应性能影响,Simulink仿真结果和有限元模拟结果的准确性较高,力学参数辨识性能优越,计算结果准确可靠。     

Seismic safety of high concrete dams

China is a country of high seismicity with many hydropower resources. Recently,a series of high arch dams have either been completed or are being constructed in seismic regions,of which most are concrete dams. The evaluation of seismic safety often becomes a critical problem in dam design. In this paper,a brief introduction to major progress in the research on seismic aspects of large concrete dams,conducted mainly at the Institute of Water Resources and Hydropower Research(IWHR) during the past 60 years,is presented. The dam site-specific ground motion input,improved response analysis,dynamic model test verification,field experiment investigations,dynamic behavior of dam concrete,and seismic monitoring and observation are described. Methods to prevent collapse of high concrete dams under maximum credible earthquakes are discussed.     

近断层地震动对上承式拱桥动力响应的影响

为了揭示近断层地震作用下上承式钢筋混凝土拱桥的动力响应特点,以西南山区某上承式拱桥为背景,用OpenSEES平台建立了全桥非线性动力分析模型,探讨了近断层地震动的输入方式、脉冲效应和竖向地震动等三个关键因素对桥梁动力响应的影响规律。研究结果表明:地震输入方式对拱圈地震响应的影响较小,但对拱上立柱地震响应的影响很大,尤其是拱顶附近的短立柱,在抗震分析中,建议偏安全地采用三向地震输入方式;脉冲效应对拱桥地震响应的影响非常大,会导致拱圈、拱上立柱和桥面板地震响应大幅增加,桥面板残余平面转角甚至增大6倍以上;竖向地震动对拱圈轴力和面内弯矩、拱上立柱纵向弯矩和剪力的影响很大,拱顶处的面内弯矩放大倍数最大可达2.95,总体来说,采用规范所建议的方法考虑竖向地震是偏保守的。     

Traveling wave effect on the seismic response of a steel arch bridge subjected to near fault ground motions

In the 1990s, several major earthquakes occurred throughout the world, with a common observation that near fault ground motion (NFGM) characteristics had a distinct impact on causing damage to civil engineering structures that could not be predicted by using far field ground motions. Since then, seismic responses of structures under NFGMs have been extensively examined, with most of the studies focusing on structures with relatively short fundamental periods, where the traveling wave effect does not need to be considered. However, for long span bridges, especially arch bridges, the traveling wave (only time delay considered) effect may be very distinct and is therefore important. In this paper, the results from a case study on the seismic response of a steel arch bridge under selected NFGMs is presented by considering the traveling wave effect with variable apparent velocities. The effects of fling step and long period pulses of NFGMs on the seismic responses of the arch bridge are also discussed.     

Hydrodynamic effects in dynamic response of simple arch dams

The dynamic responses of simple arch dams, with different radius to height ratios are analysed for three conditions: the dam alone without water, and the dam with full reservoir, considering water to be compressible in one case and neglecting water compressibility in the other case. The complex frequency response functions for accelerations at the dam crest due to the three components of ground motion—upstream-downstream component, cross-stream component and vertical component–are presented. Based on these results, the effects of dam-water interaction, of water compressibility, and of bank motions on dam response are investigated.     

大跨度拱桥地震动输入模式研究

地震动输入是大跨度桥梁地震反应分析的重要一环。从明确大跨度拱桥的临界跨度入手,探讨了大跨度拱桥地震动输入模式中的行波效应、三向输入及其地震动选取问题。基于某大跨度钢管混凝土拱桥,建立了有限元分析模型,考查了行波效应及三向地震动输入对拱关键截面内力、减隔震支座位移及粘滞阻尼器冲程的影响。结果表明:给出的大跨度拱桥临界跨度确定方法合理,行波效应对拱顶轴力有重要影响,不考虑三向地震动同时作用会明显低估大跨度拱桥的地震反应。确定大跨度拱桥地震动输入模式时需考虑行波效应与三向地震动同时输入。     

Nonuniform earthquake input for arch dam–foundation interaction

Wave scattering and dam–foundation interaction are important aspects of a realistic earthquake analysis of arch dams. In the first part of this paper it is shown how the motion obtained from a two-dimensional scattering analysis can be used as an input for a three-dimensional dam–foundation analysis. In the second part, a method for calculating the scattered motion is explained. The scattered motion is obtained via the two-dimensional dynamic stiffness matrix. The dynamic stiffness matrix for an out-of-plane motion is calculated by the Complementary-Domain Method (CDM). Some examples are presented to verify the method and to show the influence of the scattering of the seismic ground motion.     

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。     

Seismic performance evaluation of steel arch bridges against major earthquakes. Part 1: dynamic analysis approach

In this study the inelastic behavior of steel arch bridges subjected to strong ground motions from major earthquakes is investigated by dynamic analyses of a typical steel arch bridge using a three‐dimensional (3D) analytical model, since checking seismic performance against severe earthquakes is not usually performed when designing such kinds of bridge. The bridge considered is an upper‐deck steel arch bridge having a reinforced concrete (RC) deck, steel I‐section girders and steel arch ribs. The input ground motions are accelerograms which are modified ground motions based on the records from the 1995 Hyogoken‐Nanbu earthquake. Both the longitudinal and transverse dynamic characteristics of the bridge are studied by investigation of time‐history responses of the main parameters. It is found that seismic responses are small when subjected to the longitudinal excitation, but significantly large under the transverse ground motion due to plasticization formed in some segments such as arch rib ends and side pier bases where axial force levels are very high. Finally, a seismic performance evaluation method based on the response strain index is proposed for such steel bridge structures. Copyright © 2004 John Wiley & Sons, Ltd.     

Earthquake response of arch dams to spatially varying ground motion

The response of two arch dams to spatially varying ground motions recorded during earthquakes is computed by a recently developed linear analysis procedure, which includes dam–water–foundation rock interaction effects and recognizes the semi‐unbounded extent of the rock and impounded water domains. By comparing the computed and recorded responses, several issues that arise in analysis of arch dams are investigated. It is also demonstrated that spatial variations in ground motion, typically ignored in engineering practice, can have profound influence on the earthquake‐induced stresses in the dam. This influence obviously depends on the degree to which ground motion varies spatially along the dam–rock interface. Thus, for the same dam, this influence could differ from one earthquake to the next, depending on the epicenter location and the focal depth of the earthquake relative to the dam site. Copyright © 2009 John Wiley & Sons, Ltd.     

Dam-foundation rock interaction effects in frequency-response functions of arch dams

The linear response of a selected arch dam to harmonic upstream, vertical or cross-stream ground motion is presented for a wide range of the important system parameters characterizing the properties of the dam, foundation rock, impounded water and reservoir boundary materials. Based on these frequency-response functions, the dam-foundation rock interaction effects in the dynamic response of arch dams are investigated.