Intensity measures for the seismic response evaluation of buried steel pipelines under near-field pulse-like ground motions

Ground-motion Intensity Measures (IMs) are used to quantify the strength of ground motions and evaluate the response of structures. IMs act as a link between seismic demand and seismic hazard analysis and therefore, have a key role in performance-based earthquake engineering. Many studies have been carried out on the determination of suitable IMs in terms of effi ciency, suffi ciency and scaling robustness. The majority of these investigations focused on ordinary structures such as buildings and bridges, and only a few were about buried pipelines. In the current study, the optimal IMs for predicting the seismic demand of continuous buried steel pipelines under near-fi eld pulse-like ground motion records is investigated. Incremental dynamic analysis is performed using twenty ground motion records. Using the results of the regression analysis, the optimality of 23 potential IMs are studied. It is concluded that specifi c energy density (SED) followed by VSI[ω1(PGD+RMSd )] are the optimal IMs based on effi ciency, suffi ciency and scaling robustness for seismic response evaluation of buried pipelines under near-fi eld ground motions.

Seismic fragility analysis of clay-pile-pier systems considering the optimization of ground motion intensity measures

The performance of clay-pile-pier system under earthquake shaking was comprehensively examined via three-dimensional finite element analyses,in which the complex stress-strain relationships of a clay and piled pier system were depicted by a hyperbolic-hysteretic and an equivalent elastoplastic model,respectively.One hundred twenty ground motions with varying peak accelerations were considered,along with the variations in bridge superstructure mass and pile flexural rigidity.Comprehensive comparison studies suggested that peak pile-cap acceleration and peak pile-cap velocity are the optimal ground motion intensity measures for seismic responses of the pier and the pile,respectively.Furthermore,based on two optimal ground motion intensity measures and using curvature ductility to quantify different damage states,seismic fragility analyses were performed.The pier generally had no evident damage except when the bridge girder mass was equal to 960 t,which seemed to be comparatively insensitive to the varying pile flexural rigidity.In comparison,the pile was found to be more vulnerable to seismic damage and its failure probabilities tended to clearly reduce with the increment of pile flexural rigidity,while the influence of the bridge girder mass was relatively minor.

Correlation study between ground motion intensity measure parameters and deformation demands for bilinear SDOF systems

The correlation between ground motion intensity measures （IM） and single-degree-of-freedom （SDOF） deformation demands is described in this study. Peak ground acceleration （APG）, peak ground velocity （VPG）, peak ground displacement （DPG）, spectral acceleration at the first-mode period of vibration [As（T1）] and ratio of VPG to APG are used as IM parameters, and the correlation is characterized by correlation coefficients p. The numerical results obtained by nonlinear dynamic analyses have shown good correlation between As（T1） or VPG and deformation demands. Furthermore, the effect of As（T1） and VPG as IM on the dispersion of the mean value of deformation demands is also investigated for SDOF systems with three different periods T=0.3 s, 1.0 s, 3.0 s respectively.

Vector-intensity measure based seismic vulnerability analysis of bridge structures

This paper presents a method for seismic vulnerability analysis of bridge structures based on vector-valued intensity measure （viM）, which predicts the limit-state capacities efficiently with multi-intensity measures of seismic event. Accounting for the uncertainties of the bridge model, ten single-bent overpass bridge structures are taken as samples statistically using Latin hypercube sampling approach. 200 earthquake records are chosen randomly for the uncertainties of ground motions according to the site condition of the bridges. The uncertainties of structural capacity and seismic demand are evaluated with the ratios of demand to capacity in different damage state. By comparing the relative importance of different intensity measures, Sa（T1） and Sa（T2） are chosen as viM. Then, the vector-valued fragility functions of different bridge components are developed. Finally, the system-level vulnerability of the bridge based on viM is studied with Duunett- Sobel class correlation matrix which can consider the correlation effects of different bridge components. The study indicates that an increment IMs from a scalar IM to viM results in a significant reduction in the dispersion of fragility functions and in the uncertainties in evaluating earthquake risk. The feasibility and validity of the proposed vulnerability analysis method is validated and the bridge is more vulnerable than any components.

Seismic response and correlation analysis of a pile-supported wharf to near-fault pulse-like ground motions

Earthquake investigations have shown that near-fault pulse-like(NF-P)ground motions have unique characteristics compared to near-fault non-pulse-like(NF-NP)and far-field(FF)ground motions.It is necessary to study the seismic response of pile-supported wharf(PSW)structures under NF-P ground motions.In this study,a three-dimensional finite element numerical model is created to simulate a PSW.By imparting three types of ground motion,the engineering demand parameters(EDPs)of PSW under NF-P ground motions were analyzed and compared,in which EDPs are the maximum displacement and bending moment of the piles.Twenty intensity measures(IMs)were selected to characterize the properties of ground motions.The correlation between IMs and EDPs was explored.The results show that the piles present larger displacement and bending moment under NF-P ground motions compared to NF-NP and FF ground motions.None of the IMs have a high correlation with EDPs under NF-P ground motions,and these IMs are more applicable to FF ground motions.The correlation coefficients between EDPs and IMs under three types of ground motion were obtained,which will provide a valuable reference for the seismic design of PSWs.

An improved ground motion intensity measure for super high-rise buildings

Ground motion intensity measure (IM) is an important part in performance-based seismic design. A reasonable and efficient IM can make the prediction of the structural seismic responses more accurate. Therefore, a more reasonable IM for super high-rise buildings is proposed in this paper. This IM takes into account the significant characteristic that higher-order vibration modes play important roles in the seismic response of super high-rise buildings, as well as the advantages of some existing IMs. The key parameter of the proposed IM is calibrated using a series of time-history analyses. The collapse simulations of two super high-rise buildings are used to discuss the suitability of the proposed IM and some other existing IMs. The results indicate that the proposed IM yields a smaller coefficient of variation for the critical collapse status than other existing IMs and performs well in reflecting the contribution of higher-order vibration modes to the structural response. Hence, the proposed IM is more applicable to seismic design for super high-rise buildings than other IMs.

Some considerations on the physical mea-sure of seismic intensity

The study on seismic intensity can be traced prior to the time that modern seismology was established. In its early stage the seismic intensity was designed to serve as a measure in scaling the severity of earthquake damage to civil engineering and environmental structures. Also the seismic intensity is usually assigned by engineers and seismologists with one or two characteristic parameters of earthquake ground motions to reflect earthquake damage potential so as to be able to serve as an input earthquake load for seismic design of structures. So choosing a proper parameter to reflect the action of seismic intensity is the main objective of the research on physical measure of seismic intensity. However, since various kinds of structures have quite different damage mechanisms, there will exist great differences in damages to different structures located at the same area during the same earthquake. Particularly, in some cases, quite different damages have happened even to the structures of same kind due to many other factors such as different construction materials, different configurations or on the different types of sites where structures located. In addition, the ground motion parameters, which result in damage to structures, are not the single peak value of ground motion. Hence, this paper emphasizes that the research on new physical measure of seismic intensity should not only consider the structural characteristics but also take into account other parameters such as duration, energy of ground motion and so on. In particular, as the physical measures of intensity, different ground motion parameter should be adopted for different structures.

面向抗倒塌地震动强度指标选取的特征选择算法性能评估

为了筛选有效预测结构倒塌能力的地震动强度指标,对比分析了MIC、ReliefF、XGBoost和Lasso这4种常见特征选择算法用于地震动强度指标筛选时的性能。基于单自由度结构增量动力分析结果及地震动强度指标建立特征选择回归模型,根据回归模型输出权重及频数得到欧氏距离大小排序并筛选地震动强度指标,利用筛选结果对特征选择算法的性能进行评估。同时基于2层、4层、8层和12层钢筋混凝土框架结构的增量动力分析结果对筛选后强度指标建立最小二乘回归模型,以残差的标准差变化衡量不同特征选择算法筛选出的地震动强度指标对结构倒塌的预测能力。结果表明:基于Lasso回归算法筛选的地震动强度指标比其他算法用于结构倒塌预测时准确率提高31%。结果可为基于性能地震工程(performance-based earthquake engineering,PBEE)框架下结构易损性分析中及地震动不确定性分析中地震动强度指标筛选的特征选择算法提供参考,也可为结构倒塌预测的地震动强度指标筛选提供有效特征选择算法参考。

基于矢量IMs的浅埋偏压黄土隧道地震易损性

为从概率角度对浅埋偏压黄土隧道的地震易损性进行定量评价,采用基于黏弹性边界的波动输入方法,并通过增量动力分析对土-结构相互作用有限元模型进行大量非线性动力时程计算,评估20个地震动强度参数(IMs),然后基于标量IM和矢量IMs分别对浅埋偏压黄土隧道展开地震易损性分析.结果表明:地表峰值速度(效益性指标ζ=0.15)是最适合的IM,其次是速度谱强度(ζ=0.20)和谱速度峰值(ζ=0.22);相比于标量IM,基于矢量IMs的拟合效果更好,可降低结构损伤预测的离散性;在建立地震易损性曲面时需考虑2个IMs之间相关性的影响以确定曲面的有效取值范围;采用标量IM会低估或高估隧道实际的损伤概率.基于矢量IMs可对隧道的地震易损性作出更准确的评估.

近断层地震动作用下浅埋综合管廊地震易损性研究

为准确评估近断层地震动作用下浅埋综合管廊的地震损伤,利用ABAQUS建立土-结构整体有限元模型,以综合管廊层间位移角最大值为损伤指标,基于IDA方法进行结构地震易损性分析,重点考察近断层地震动强度指标和场地土特性对综合管廊抗震性能的影响。结果表明:近断层地震动加速度型指标的离散性最小,建议选取加速度型指标PGA、Sa作为地震动强度指标;以有限元计算数据为样本,采用BP神经网络可高效预测综合管廊结构的地震损伤,PGA、Sa及土体剪切模量对综合管廊地震易损性分析的影响较大,随着土体剪切模量的增大,超越概率逐渐减小,同时,LS、CP状态的超越概率变化范围要明显大于OP、IO状态;考虑PGA和Sa双参数更能准确反映不同地震动参数对结构损伤的影响,而仅考虑PGA或Sa单参数有可能高估结构的损伤程度。因此,对综合管廊等浅埋地下结构进行地震易损性分析时,建议综合考虑PGA和Sa的影响。

基于广义条件强度参数的水平和竖向地震动联合选取研究

为了合理地考虑竖向地震作用和实现水平和竖向地震动的联合选取,提出了基于广义条件强度参数的水平和竖向地震动联合选取方法:扩展广义条件强度参数的基本理论,提出水平和竖向地震动广义条件强度参数分布的构建方法,并与“无条件分布”对比,提出基于广义条件强度参数的水平和竖向地震动联合选取方法的基本理论,给出以水平强度参数作为条件的实际算例,利用现有水平-水平、水平-竖向强度参数相关系数模型构建水平和竖向地震动广义条件强度参数目标分布,对目标地震动数据库进行联合选取,将选取结果与传统选取方法进行对比,说明该方法的合理性。结果表明:构建出的水平和竖向广义条件强度参数分布与“无条件”分布之间存在一定差异;水平和竖向地震动联合选取结果与目标理论分布匹配良好;与仅考虑水平向广义条件强度参数地震动选取方法相比,联合选取方法能够考虑竖向地震动特性,并且不会对水平向造成影响,提出的水平和竖向地震动联合选取方法能够更加合理地、全面地考虑水平和竖向地震动特性,为工程结构在水平和竖向地震动作用下的抗震性能研究提供地震动输入基础。

基于IDA的输电塔地震动强度指标与结构损伤指标研究

以输电塔为研究对象,利用20条典型地震动时程,分别采用10个地震动强度指标(intensity measure,IM)和4个结构损伤指标(damage measure,DM)对输电塔进行增量动力分析(incremental dynamic analysis,IDA)。通过双对数线性回归建立了地震动强度指标与输电塔损伤指标的无量纲化关联模型,并对不同强度指标和损伤指标组合下关联模型的有效性、实用性和效益性进行了综合评价。结果表明:针对输电塔结构,选取有效峰值加速度(effective peak acceleration,EPA)作为IM和节间位移角(inter-story drift ration,ISDR)作为DM进行组合时,具有较好的稳定性和较高的相关性;基于输电塔结构第一阶、第二阶反应谱的Sa_(avg)^(*)在指标关联性评价中的优势与EPA、Sa(T_(1))类似,而Sv*avg指标与有效峰值速度(effective peak velocity,EPV)、第一周期谱速度(Sv(T_(1)))指标相比,增强了与DM之间的关联性;构造的E(ad)作为结构总持时内的地震动能量输入指标与所有IM指标组合时,并不受输电塔对加速度型IM更敏感从而导致加速度型IM与DM组合时关联性更强的影响。研究结果可以为进一步提高输电塔结构抗震性能评价精度提供参考和借鉴。

基于向量地震动强度指标的拱坝地震易损性分析

将地震动顺河向分量的一、二阶谱加速度以及地震动横河向、顺河向分量的一阶谱加速度分别作为反映地震动强度的向量指标,建立了以拱冠位移、横缝开度和损伤体积比为性能指标的拱坝地震易损性曲面,以预测拱坝在不同强度水平的地震作用下达到各级破损的概率。以白鹤滩拱坝为研究对象,考虑地震动以及材料的不确定性对拱坝进行增量动力分析,将分析结果取对数后进行二元线性回归,得到概率地震需求模型,然后建立了不同性能指标的拱坝地震易损性曲面,并对基于向量地震动强度指标和基于标量地震动强度指标进行拱坝地震易损性分析的效率进行了比较。研究结果表明:基于向量IM的易损性分析能够显著降低拱坝地震需求预测的离散性,同时基于向量IM比标量IM更加高效,采用基于向量IM的地震易损性曲面对拱坝进行易损性分析能更加准确地评估拱坝的抗震性能。

关于地震烈度物理标准研究的若干思考

自从现代地震学形成以来, 人们一直沿用地震烈度来度量地震的破坏后果和破坏程度, 地震工程师也致力于给地震烈度赋以恰当的物理量, 一方面旨在解释地震的破坏作用,同时也希望能用这个物理量来代表地震对结构的一种输入荷载, 以供工程抗震设计使用. 这就是研究“地震烈度物理标准”工作的任务. 但是由于不同结构的破坏机理很不相同, 甚至同一类结构由于层高、使用的材料以及所在场地的差别, 即使在同一地震作用下, 其震害也会有很大的差异. 此外, 导致结构破坏的地震动因素也十分复杂, 绝不限于地震动峰值一个因素. 因此本文指出, 新的烈度标准应不仅能反映各种结构的具体特点, 还应在研究地震动幅值参数的同时进一步考虑与地震动能量有关的参数, 特别是针对不同结构应采用不同的地震动参数.

超高层建筑地震动强度指标探讨

地震动强度指标是建筑结构抗震设计的重要依据。该文以弯-剪耦合梁模型为基础,建立超高层建筑的简化分析模型,分析不同地震动强度指标与超高层建筑结构抗震设计控制指标的相关性、离散度及其随结构基本周期的变化规律。并通过上海中心大厦(高632 m)的倒塌分析实例对不同地震动强度指标的适用性进行验证。结果表明:PGV与超高层结构的层间位移角响应具有较好的相关性,且离散度最小,可作为超高层建筑结构抗震分析和地震响应分析的地震动强度指标。

概率性地震需求分析中地震动强度指标的比较与选择

以汶川地区典型钢筋混凝土简支梁桥为背景,在充分考虑模型参数不确定性的基础上建立一系列桥梁有限元模型样本。采用汶川地震实测地震动,对建立的有限元模型进行非线性动力时程分析,并记录每组分析中桥梁构件的地震峰值响应。采用主成分分析方法对桥梁构件的地震需求参数进行降维处理,计算桥梁结构综合地震需求响应。通过回归分析建立地震动强度与桥梁结构综合需求之间的概率性关系,并对不同地震动强度指标进行分析和比较。结果表明基于速度的地震动强度指标具有较好的有效性、适用性和完备性,可以进一步用于地震易损性分析和地震风险评估。

基于砌体结构破坏损伤的地震烈度物理标准研究

为了研究基于砌体结构破坏的地震烈度物理标准,将15个地震动参数按属性(峰值、频率、持时和能量)分成4类,将地震记录按地震动三要素(峰值、频率、持时)分成3组,求出每组记录作用下砌体结构的延性系数,计算出各个参数值和延性系数的相关系数,比较分析这些相关系数发现地震动峰值加速度、有效峰值加速度、地震动输入能量和滞回耗能都能表征地震动对砌体的破坏势,并且这4个参数都和烈度有很好的相关性,可以作为烈度的物理标准。

近断层地震动作用下桥梁结构易损性曲面分析

本文将易损性曲面方法拓展应用于近场地震动潜在破坏性效应对桥梁结构的影响分析,考虑近场和一般场地地震动效应,对某钢筋混凝土(RC)桥梁结构地震易损性进行了分析。该方法综合考虑了RC桥梁本身和烈度指标(IM)的不确定性以及桥梁体系的损伤特性,以评估近场地震效应的潜在破坏性。以一座城市桥梁为例,易损性分析结果表明:对RC桥梁结构进行地震易损性分析时,单一标量IM会低估地震动潜在破坏性效应,近场地震效应会增加桥梁结构的损伤概率。与传统标量的易损性曲线相比,本文方法可以有效地反映地震动烈度引起的RC桥梁结构失效概率变化。

考虑场地条件与设计地震分组的输入能量谱研究

建立简单适用的设计输入能量谱是将能量方法应用于实际工程设计及校核的前提.选择了Ⅰ类、Ⅱ类和Ⅲ类场地共694条水平地震动记录,分析了不同的场地类别和设计地震分组下输入能量谱的特点.通过12个不同地震动参数与能量谱值的相关性分析,得到了表征地震动输入能量的地震动参数.基于我国现行规范规定的设防烈度和设防水准,提出了地震分组指标,并建立了相应的阻尼比为5%的弹性单自由度体系设计输入能量谱,为应用能量设计法及选择地面运动输入奠定了基础并提出相关建议.

速度脉冲型地震地面运动强度表征参数评估

研究强速度脉冲型地震地面运动强度表征参数(IM)与单自由度(SDOF)体系非线性变形需求的相关性,并分析IM的有效性。采用72条速度脉冲型地震记录,基于SDOF体系的动力时程分析,研究了恒延性水平(μ)和恒强度折减系数(R)条件下脉冲型地面运动IM与最大非线性变形相关性系数的变化规律;通过线性回归和离差分析,研究了加速度反应谱(Sa(T1))和峰值地面运动速度(PGV)作为脉冲型地面运动IM的有效性。分析结果表明,脉冲型地面运动IM对体系周期有很强的依赖性,μ和R对相关性和离散性均有很大影响,Sa(T1)和PGV是相对较优的脉冲型地面运动IM。