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.

Long-period ground motion characteristic of the 1999 Jiji (Chi-Chi),Taiwan,main-shock and aftershocks

This paper investigates long-period ground motion characteristic of the 1999 Jiji （Chi-Chi）, Taiwan, mainshock and aftershocks on the basis of lots of high quality digital strong motion records. The study attaches the importance to the variation of strength of the long-period ground motion with the magnitude, distance, and site condition. In the meantime, the near-fault long-period ground motion characteristic is analyzed. The result shows that the shape of the long-period response spectrum is mainly controlled by site condition and magnitude （the spectrum of class D＋E is wider than that of class B＋C, and the spectrum of larger magnitude is wider than that of smaller magni- tude）, and the effect of fault distance on the shape is not evident. And near-fault long-period ground motion characteristic depends on fault activity apparently, that is to say, the long-term ground motion in the hanger is stronger than that in the footwall, and the long-term ground motion in the north is stronger than that in the south.

Acomparative study between China and U.S.on seismic design philosophy and practice of a long span arch bridge

This paper presents the first of a series of case studies on the seismic design of long span bridges （cable-stayed bridges, suspension bridges and arch bridges） under a cooperative research project on seismic behavior and design of highway bridges between the State Key Laboratory for Disaster Reduction in Civil Engineering, Tongji University and the Multidisciplinary Center for Earthquake Engineering Research, University at Buffalo. The objective of this series of case studies is to examine the differences and similarities on the seismic design practice of long span bridges in China and the U.S., to identify research needs and to develop design guidelines beneficial to bridge engineers in both countries. Unlike short to medium span bridges, long span bridges are not included in most seismic design specifications, mainly because they are location dependent and structurally unique. In this paper, an available model of a steel tied half through arch bridge with a main span of 550m in China is discussed. Analysis is focused on comparisons of the seismic responses due to different ground motions. Seismic design criteria and seismic performance requirements for long span bridges in both countries were first introduced and compared, and then three near field earthquake records with large vertical components were selected as the excitations to examine the seismic behavior and seismic vulnerability of the bridge. Results show that （1） the selected near field ground motions cause larger responses to key components （critical sections） of the bridge （such as arch rib ends） with a maximum increase of more than twice those caused by the site specific ground motions; （2） piers, longitudinal girders and arch crowns are more vulnerable to vertical motions, especially their axial forces; and （3） large vertical components of near field ground motions may not significantly affect the bridge＇s internal forces provided that their peak acceleration spectra ordinates only appear at periods of less than 0.2s. However, they may have more influence on the longitudinal displacements of sliding bearings due to their large displacement spectra ordinates at the fundamental period of the bridge.

Site dependence of far-source ground motions during the Wenchuan earthquake

This paper aimed to examine the site dependence and evaluate the methods for site analysis of far-source ground motions. This was achieved through the examination of frequency content estimated by different methods based on strong ground motions recorded at twelve far-source stations in Shandong province during the Wenchuan earthquake. The stations were located in sites with soil profiles ranging from code classes Ⅰ to Ⅲ. Approaches used included the Fourier amplitude spectrum （FAS）, the earthquake response spectrum （ERS）, the spectral ratio between the horizontal and the vertical components （H/V）, the spectral ratio between the spectra at the site and at a reference site （SRRS）, and coda wave analysis （CWA）. Results showed that major periods of these ground motions obtained by FAS, ERS and H/V ratio methods were all evidently larger than site dominant periods; the periods were also different from each other and mainly reflected the frequency content of long period components. Prominent periods obtained by the SRRS approach neither illuminated the long period aspect nor efficiently determined site features of the motions. The CWA resulted in a period close to site period for stations with good quality recordings. The results obtained in this study will be useful for the evaluation of far-source effect in constructing seismic design spectra and in selecting methods for ground motion site analysis.

长持时地震动对建筑结构抗震影响的研究进展

该文综述了长持时地震动作用下建筑结构抗震性能的研究进展。介绍了长持时地震动的定义和特性;梳理了长持时地震动作用下建筑结构数值模拟、试验研究和理论分析的研究进展;详细综述了长持时地震动作用下建筑结构的延性性能、耗能能力、易损性和抗倒塌性能的研究进展。此外,介绍了考虑长持时地震作用影响的建筑结构抗震设计方法,梳理了国内外建筑结构抗震设计规范对长持时地震作用的考虑方法,并对长持时地震动作用下建筑结构抗震性能的研究进行了展望。建议关注长持时地震动作用下建筑结构的抗震性能,进一步研究长持时地震动的定义和特性,改进长持时地震动作用下建筑结构的数值模拟、理论分析和试验研究方法,深入探讨长持时地震动作用下各类建筑结构的地震响应、易损性和抗倒塌性能,为未来结构抗震设计及评估中考虑长持时地震作用的影响和规范修订提供参考。

近远场地震下RC大跨轻柔拱桥减隔震支座方案优化

为探明不同地震动输入对某大跨轻柔拱桥减隔震的影响,通过非线性有限元模型分析近远场地震下桥梁结构的响应规律,得到大桥支座的优化布置方案.首先,基于模态分析,对比该桥与传统钢筋混凝土(RC)拱桥动力特性差异;其次,选取不同脉冲周期的近场地震动、近场无脉冲及远场长周期地震动记录;最后,研究近远场地震下拱桥的响应行为和损伤演化路径,得到优化桥梁的减隔震支座设计方案.研究结果表明:近场脉冲及远场长周期地震下的桥梁结构响应大于无脉冲地震响应;纵竖向地震下高墩柱剪力及弯矩包络曲线呈“S”形,墩身中部易形成塑性铰,高阶振型影响显著;桥梁纵桥向先于横向震损,损伤路径依次为矮柱、高墩柱及拱肋实心-空心截面段;摩擦摆支座减震效果最佳但位移较大,高阻尼支座方案在近场中长脉冲周期及远场长周期地震下仍会发生损伤,板式橡胶支座方案因无法保证支座同步滑移而不能形成准隔震体系;“高阻尼+摩擦摆”混合方案的支座位移小,拱肋及墩柱均处于弹性,是近断层大跨轻柔RC拱桥的优选减隔震方案.

海底长周期地震动预测模型:以日本相模湾海域为例

地震动反应谱预测模型是地震危险性分析的基础,基于日本K-NET台网相模湾地区的892组海域地震动数据和4 033组陆域地震动数据,考虑震级、震源距、震源深度以及震源类型和场地,建立了PGA和0.05~15.0 s的海域地震动加速度反应谱预测模型。通过残差分析以及相关性分析检验了模型的合理性,并分析了震源类型以及震源深度对反应谱的影响,对比了海陆地震动预测模型的差异。结果表明:震源类型以及震源深度对模型预测结果影响显著,水平向海域模型以及长周期(T≥1.0 s)竖向海域模型所预测反应谱大于陆域模型所预测的反应谱值,且水平向和长周期竖向模型的场地放大系数均大于1。该模型可为长周期海域地震动模型的建立和概率地震危险性分析提供参考,为长周期海域工程的抗震设防提供依据。

跨走滑断层大跨度桁架悬索桥地震响应分析

跨越断层的长大跨度桥梁难免会受到断层错动作用,为探究跨走滑断层地震动参数对大跨度悬索桥地震响应的影响,以某主跨为538 m的钢桁架悬索桥为例,利用ABAQUS建立考虑桩-土相互作用(“m”法)的全桥有限元模型。通过叠加人工低频地震成分和实际高频地震成分,合成了跨走滑断层地震动,采用非一致激励位移时程法,重点分析永久位移、脉冲周期和跨断层角度对大跨度悬索桥的动力响应影响。结果表明:随着永久位移增大,桥塔动力响应呈不同幅度的增长,特别是横桥向位移、剪力,以及顺桥向弯矩增幅比较明显,分别增大97%、88%和95%,且剪力的增大加剧了桥塔发生剪切破坏的风险;随着脉冲周期减小,桥塔沿顺桥向和横桥向的动力响应增幅差距较大,当脉冲周期小于4 s时,桥塔横桥向位移、剪力,以及顺桥向弯矩相较于另一方向增幅更为明显,其增幅分别为492.5%、170%和189.2%;跨断层角度对桥塔的动力响应影响较大,且沿顺桥向和横桥向的响应变化趋势相反,跨断层角度为90°时,桥塔横桥向位移、剪力取得最大值,而弯矩取得最小值,且桥塔动力响应均在合理范围内,为最佳跨越角度。

远场长周期地震动作用下超高层建筑结构模态识别

远场地震动长周期成分显著,与高层、超高层建筑基本周期相近,容易产生放大效应,给高层、超高层建筑结构带来严重震害。以2022年9月17日21时41分至次日17时39分发生在台湾省花莲县M6.5、M5.7、M6.9和M 5.4地震为例,利用Hilbert-Huang Transform(HHT)方法,初步分析距震中超1000 km的武汉某超高层建筑结构台阵对这4次地震的结构动力响应观测数据,在对不同时间尺度的本征模态函数分量进行地震动长周期特性分析的基础上,重构各结构层的地震动,通过功率谱法得到结构层相对地面层的频率响应函数,并利用复模态指数函数法获得结构第一阶模态频率和振型。对4次地震中该超高层建筑结构模态频率和振型的初步分析表明:在花莲长周期地震动作用下结构未受到损伤。这一认识将为远场长周期地震动影响下超高层建筑的震后安全性评价提供重要参考。

长周期地震动对SRC框架-RC核心筒混合结构协同工作的影响

长周期地震动因含有丰富的低频成分易使(超)高层建筑等长周期结构发生严重震害。SRC(steel reinforced concrete)框架-RC(reinforced concrete)核心筒混合结构作为广泛应用于高烈度区的双重抗侧力结构体系,确保其强震下的协同工作是实现多道抗震防线,形成合理破坏模式的关键。该文通过与普通地震动对比,阐明了远场长周期地震动对SRC框架-RC核心筒混合结构协同工作的影响规律,并基于谐振激励下的结构动力分析模型及经验模态分解初步揭示了其内在机理。算例分析结果表明:受低频特性影响,远场长周期地震动作用下结构框架剪力分担率与底层倾覆力矩占比明显大于普通地震动,最大框架剪力分担率所在楼层与普通地震动相比出现下移,且当峰值加速度增至400 gal时,SRC框架中下部楼层剪力分担率超过40%,底部倾覆力矩占比超过70%,按照现行规范设计的SRC框架将难以保证远场长周期地震动作用下结构的抗震安全;激励频率对于SRC框架-RC核心筒混合结构协同工作的影响与振型参与方式有关,低频激励(周期为0.5倍~2.0倍结构基本周期)下结构响应主要受低阶振型主导;远场长周期地震动的卓越分量是导致框架剪力分担率增大的原因。

不同类型地震动下RC框剪结构协同工作对比分析

确保强震下双重抗侧力结构的协同工作是实现多道抗震防线的关键。基于地震动特性分析,对比了普通地震动、远场长周期地震动、近断层向前方向性地震动及近断层滑冲型地震动作用下RC框架-剪力墙结构的协同工作性能,并分析了刚度特征值及结构周期对其的影响;最后初步提出了特殊地震动作用下RC框架-剪力墙结构考虑内力重分配的框架剪力调整方法,并将其与规范中的调整方法进行了对比。结果表明:三类特殊地震动作用下的框架剪力分担率均大于普通地震动,尤其是远场长周期地震动,在地震动强度较小时也能使框架剪力出现较大增长;周期较大结构的中下部楼层框架剪力增大较快;结构框架剪力分担率随刚度特征值的增大而增大,但内力重分配程度逐渐减小;建议在结构抗震设计时,考虑不同类型地震动特性和刚度特征值对结构内力重分配的影响。

不同场地类别对反应谱特征周期的影响

为探究不同场地类别对反应谱特征周期的影响,建立了包含四种场地类别的180个计算剖面,在现行《建筑抗震设计规范》GB 50011—2010中场地分类的基础上按照土的软硬程度进一步细分,以不同幅值的El Centro地震动作为输入地震动,采用一维等效线性化方法进行土层反应分析,计算得到场地地震动反应谱,规准化得到反应谱特征周期。结果表明:①在同一类别场地中,随着等效剪切波速的增大,特征周期呈减小的趋势;②在同一类别场地中,随着输入地震动强度的增大,特征周期也相应增大;③在不同类别场地中,输入相同的地震动,场地类别从Ⅰ类到Ⅳ类,反应谱特征周期逐渐增大。最后,根据细分后的场地类型给出了其反应谱特征周期建议值,并进行了验证。

日本地震预警系统研究综述

为深入了解日本地震预警系统在防震减灾中的有效应用,本文首先,介绍了日本地震预警系统的研究现状,包括铁路地震预警系统、陆域和海域地震预警系统以及长周期地震预警系统;其次,阐述了预警发布标准、发布方式和发布后的避险措施,总结了地震预警的特点、局限性和注意事项,讨论了我国在地震预警系统建设时遇到的问题。通过对日本地震预警系统的全面介绍和深入分析,有利于了解该系统的运行机制、应用效果以及面临的挑战,为我国地震预警事业的发展提供重要参考。

长周期地震动作用下某EPR核电站安全壳的隔震性能分析

核电站安全壳是切实有效保证核电站安全的必备设施。研究长周期地震动作用下的安全壳隔震性能,对安全壳具有十分重要的理论意义和工程应用价值。以某EPR核电站安全壳为研究模型,考虑了该安全壳自重和预应力系统,采用软件ANSYS建立复杂的三维数值仿真模型,探讨长周期地震动作用下安全壳的变形、加速度、基底剪力和预应力筋的平均应力,证实在长周期地震动作用下,该安全壳受力性能良好,并在控制范围内。基于此,引入层叠橡胶隔震器和软钢隔震器并联的新型隔震装置,进而研究长周期地震动作用下安全壳的隔震性能。分析结果表明:由于地震动的特性(例如,随机性、不确定性、空间相关性等),核电站安全壳设计必须从多方面重视长周期地震动。短周期地震动作用下新型隔震装置是有效的,长周期地震动作用下隔震失效。研究结果为核电站安全壳隔震设计提供技术指导。

3D simulation of near-fault strong ground motion: comparison between surface rupture fault and buried fault

In this paper, near-fault strong ground motions caused by a surface rupture fault （SRF） and a buried fault （BF） are numerically simulated and compared by using a time-space-decoupled, explicit finite element method combined with a multi-transmitting formula （MTF） of an artificial boundary. Prior to the comparison, verification of the explicit element method and the MTF is conducted. The comparison results show that the final dislocation of the SRF is larger than the BF for the same stress drop on the fault plane. The maximum final dislocation occurs on the fault upper line for the SRF; however, for the BE the maximum final dislocation is located on the fault central part. Meanwhile, the PGA, PGV and PGD of long period ground motions （≤ 1 Hz） generated by the SRF are much higher than those of the BF in the near-fault region. The peak value of the velocity pulse generated by the SRF is also higher than the BE Furthermore, it is found that in a very narrow region along the fault trace, ground motions caused by the SRF are much higher than by the BF. These results may explain why SRFs almost always cause heavy damage in near-fault regions compared to buried faults.

近断层地震下大跨度铁路钢桁架拱桥减震技术研究

以我国某主跨400 m的铁路钢桁架拱桥为工程背景,采用低频速度脉冲叠加高频记录底波的方法合成近断层脉冲型地震动开展动力时程分析,研究了大跨度铁路钢桁架拱桥的响应特性及纵、横桥向减震技术。结果表明,近场脉冲型强震作用下,各构件的响应较未考虑脉冲效应时明显增大,交界墩墩底及横梁、引桥墩墩底等截面破坏严重,支座破坏严重,梁台存在碰撞风险。全桥布置摩擦摆支座可降低主拱应力,但无法有效控制桥墩弯矩响应,且会放大梁端位移;“摩擦摆支座+黏滞阻尼器”的纵桥向减震方案可使主拱应力、交界墩底弯矩、梁端位移分别下降28.53%,63.23%,22.52%,减震效果明显;横桥向增设防屈曲支撑可大幅减小桥墩横梁地震响应,交界墩下、中横梁弯矩降幅分别达58.89%, 62.48%。采用上述组合减震措施可提升桥梁的整体抗震性能,满足抗震设防要求,可供同类型桥梁的减震设计参考。

长周期地震动的非弹性反应谱

根据长周期地震动的特性,选取139条长周期地震动记录,以分析结构动力参数和长周期地震动特性对长周期地震动非弹性反应谱的影响规律。研究结果表明:与常规地震动相比,恢复力模型和屈服后刚度比(η)对地震动非弹性反应谱中长周期段的影响较大,且场地土对非弹性反应谱的放大效应更为显著;相反,阻尼比(ξ)和位移延性比(μ)对常规和长周期地震动非弹性反应谱的影响规律较为类似。提出在建立长周期地震动设计谱时,应选取合理的恢复力模型和η,参考已有ξ和μ对常规地震动反应谱的影响规律,并针对不同的场地类型建立相应的设计谱;可以先建立某标准设防烈度的长周期地震动的设计谱,其他设防烈度的设计谱可用PGA_(设防)与PGA_(标准)的比值调整得到。

长周期地震下大跨RC轻柔拱桥BRB横向减震研究

为了提升长周期地震下轻柔拱桥的横向抗震性能,可在排架墩间设置屈曲约束支撑(BRB)。以某新型高墩大跨RC拱桥为研究对象,说明其结构体系的特殊之处,分析不同脉冲周期的近场地震动、远场长周期、近场无脉冲及远场普通地震动下,BRB对全桥墩柱的减震效果与损伤状态变化趋势。研究结果表明:轻柔拱桥在长周期地震动下的地震需求更高;BRB能够有效降低排架墩的变形与弯矩需求,但会在一定程度上增加设置BRB墩柱的底部剪力;在近场脉冲地震动的永久位移效应与远场长周期地震动的丰富低频分量下,应用于轻柔体系拱桥的位移相关型BRB减震效果较佳,耗能突出;而由于近场无脉冲与远场普通地震动的位移谱值始终较低,在该2类地震下会普遍出现响应放大的情况;BRB改变了排架墩的传力路径,将部分弯矩转化为连接处的剪力与轴力,同时高墩高阶振型的影响加大,导致其弯矩包络沿墩身存在突变;能有效避免未设BRB墩柱的破坏,而由于高阶振型的影响,大部分高墩截面损伤降低程度不显著;设置BRB的墩柱顶部截面损伤会降低,因立柱与拱肋的振动耦合作用,其底部截面在小震下损伤也会缓解,而过渡墩底部截面的损伤反而会增大。位移耗能型BRB在长周期地震下能有效提升轻柔体系拱桥的横向抗震性能。

隔震框架结构长周期地震动响应与损伤机理

研究目的:采用隔震技术可有效改善山地掉层框架结构的抗震性能,但山地地区常紧邻地震断裂带与大型沉积盆地,这为近断层脉冲型长周期地震动(近场型)和远场长周期地震动(远场型)的孕育提供了条件。在实际工程设计中,常常忽略长周期地震动对隔震结构的危害性,且对于长周期地震动作用下隔震结构减震性能的研究尚未完善。研究结论:(1)基于Hilbert-Huang变换(HHT)方法实现了对两类长周期地震动的特殊长周期成分的提取;(2)针对铅芯隔震掉层框架结构,将提取特殊长周期成分后的地震动的结构响应与原始地震动的响应进行对比,依据各类结构响应的改变量进一步揭示不同长周期成分对隔震框架结构的控制效应;(3)隔震框架结构在近场地震动作用下主要产生隔震垫位移过大的首次超越破坏,而在远场长周期地震动作用下除了产生较大的隔震垫位移,还需对隔震垫的能量滞回效应引起重视;(4)本研究成果可为山地建筑结构的设计提供参考。

长周期地震动作用下基础隔震结构抗倾覆能力研究

对极限高宽比的基础隔震结构进行地震响应分析,探究常规地震动与长周期地震动的差异,并从隔震层位移、隔震层拉应力以及结构的抗倾覆力矩比3种导致结构倾覆的参数入手,分析基础隔震结构在长周期地震动作用下的倾覆情况。首先,选取近断层脉冲型长周期地震动和远场类简谐长周期地震动各9条。其次,建立3种不同烈度区下极限高宽比限值时的框架隔震结构模型,分析不同设防烈度下罕遇地震对基础隔震结构隔震层支座水平变位与轴向受力的影响,以及罕遇地震时结构的抗倾覆力矩比。最后,修正高宽比限值简化公式,计算出长周期地震动作用下的理论高宽比限值,根据限值修正结构高宽比后再进行地震响应分析。研究结果表明:在长周期罕遇地震动作用下,基础隔震结构隔震支座位移量普遍超过允许限值,大量支座出现拉应力,其中部分支座拉应力超过允许限值,隔震层受到严重破坏;少数情况下结构抗倾覆比小于1.2,结构有倾覆可能;结合简化公式给出长周期地震动作用下高宽比建议值。