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1.
弹塑性地震反应谱的长周期特性研究 总被引:3,自引:1,他引:3
在基于性能抗震设计中弹塑性反应谱在计算结构地震位移反应方面越来越受到重视。利用统计分析方法研究了等强度的延性需求谱和等延性的强度折减系数谱的长周期(至5 s)区段的特性,关注的重点是等位移准则和场地条件影响。给出了若干具有工程价值的结论:一是周期介于1.5Tg(地震动特征周期)和2.5 s之间的结构可近似认为等位移准则成立且与场地条件关系不大,这样确定的强度折减系数当位移延性系数小于等于4时结果将是偏于安全的;二是结构周期大于2.5 s后以硬土场地等延性强度折减系数谱或等强度延性需求谱代替软土场地谱求解系统强度需求或延性需求,将会得到偏于安全的结果。 相似文献
2.
《地震工程与工程振动》2021,41(4)
自复位摇摆桥梁的损伤和残余位移小,具有良好的震后可恢复性。文中以自复位摇摆桥梁为研究对象,对不同类型地震动作用下的结构的延性需求谱及其影响因素进行研究。选用FEMA P695推荐的100条典型地震动作为输入,并划分为远场地震动、近场脉冲地震动以及近场无脉冲地震动。研究结果表明,近场脉冲地震动作用下的结构的延性需求最大,设计时需考虑近场脉冲地震动的影响;随着强度折减系数R的增大,结构的延性需求显著增加,设计时不宜采用较高的强度折减系数;增加刚度比α和耗能系数β能在一定周期范围内减小结构的延性需求;阻尼比ξ在0.01~0.05范围内对延性需求的影响基本可以忽略。 相似文献
3.
利用汶川地震获得的数字强震记录研究了汶川近场无速度脉冲、近场含速度脉冲和远场(盆地效应)地震动的弹性和弹塑性反应谱,后者包括等延性强度折减系数谱Rμ、等延性位移比谱Cu和等强度折减系数位移比谱CR.与相同场地条件PEER近场无速度脉冲、集集近场含速度脉冲地震动的谱进行了比较.汶川近场含速度脉冲地震动的弹性反应谱在0.2~0.8s周期内明显偏小,而它的弹塑性反应谱在短周期段(0.1 ~0.4 s)与汶川近场无速度脉冲地震动谱差别不大,但等延性强度折减系数谱Ru要大于集集地震含速度脉冲地震动的谱,而等延性位移比谱Cu和等强度折减系数位移比谱CR则小于集集地震动情况,此后随周期增长(至0.6 ~1.Os后)它们都逐渐过渡至与集集地震动的谱相当.汶川远场(盆地效应)地震动的弹性反应谱具有较宽并随周期缓慢增长的平台值和较长的特征周期,可达1.7s及以上.提出了远场(盆地效应)与近场地震动的弹性反应比谱和弹塑性位移比谱的概念. 相似文献
4.
《地震工程与工程振动》2021,41(4)
结构震后残余位移是抗震性能评估和地震损失评估的重要参数。文中针对理想弹塑性单自由度体系,采用与残余位移相关性最好的归一化参数定义残余位移比,通过动力时程分析建立统计平均的等延性残余位移比谱和等强度残余位移比谱,研究场地条件、延性系数及强度折减系数对等延性残余位移比谱和等强度残余位移比谱的影响,通过回归分析构建了等延性残余位移比谱和等强度残余位移比谱的预测方程。结果表明:残余位移与弹塑性谱位移的相关性较大,与弹性谱位移的相关性较小;软土场地下结构残余位移的评估需考虑场地条件的影响;残余位移比离散性受延性系数和强度折减系数影响显著。 相似文献
5.
强度折减系数既是基于强度的抗震设计中确定设计地震力的关键因素,又是基于性态的抗震设计理论中确定非弹性反应谱的主要依据. 本文结合我国抗震设计反应谱的形式和特点,应用823条国内外水平向地震动记录(充分利用了我国取得的强震记录),给出了一种考虑设计地震分组和场地类别的强度折减系数模型,研究了结构周期、延性、场地类别、设计地震分组、震级、震中距等因素对强度折减系数的影响. 结果表明:场地条件对强度折减系数的影响是不可忽略的,特别是对延性较大的短周期结构更应注意场地条件的影响;设计地震分组是影响强度折减系数的一个重要因素,在应用我国规范设计反应谱构造非弹性反应谱所用的强度折减系数必须考虑设计分组的影响;震级对强度折减系数的影响较小;如不考虑近场大脉冲地震动记录的影响,震中距对强度折减系数的影响是可以忽略的. 相似文献
6.
俯冲带地区竖向地震动的阻尼修正系数在工程结构抗震设计中起着重要作用。由于俯冲带地区的板块构造复杂,俯冲带地区的地震可划分为浅壳上地幔地震、板内地震和板间地震3种类型。为研究不同类型俯冲带地震的竖向地震动阻尼修正系数间是否具有显著差异而需要分别建立不同的阻尼修正系数模型,采用日本俯冲带地区的地震动数据,通过假设检验和构造差异指标的方式对不同类型地震的竖向加速度和位移反应谱的阻尼修正系数进行两两比较。结果显示:不同地震类型的竖向地震动阻尼修正系数在众多谱周期上存在统计意义和工程实际意义上的显著差异。该研究表明:研究俯冲带地区竖向地震动阻尼修正系数时需要考虑地震类型的影响。 相似文献
7.
弹塑性时程分析一般用来评估和验算结构抗震性能,如何选取合适的输入地震动是其中关键工作之一。为给结构弹塑性时程分析选取地震动提供合理的参考参数,本文讨论了地震动反应谱参数与结构地震响应之间的相关性。首先建立了6层和7层两个钢筋混凝土(RC)框架结构数值模型,分别对两个结构进行了大量地震动作用下的时程反应分析,并考察了地震反应特点;然后将结构地震响应与地震动反应谱参数建立关系并进行了相关性分析。结果表明:对RC框架而言,结构地震响应与弹性谱参数相关性较小,与等强度反应谱相关性随标准屈服强度降低而增大,与等延性反应谱相关性随延性增大而增大,而与地震动输入能量谱在标准屈服强度较小时相关性最大。建议RC框架结构在进行地震反应时程分析时,可以参考地震动的弹塑性输入能量谱、等强度速度谱和等延性加速度或位移谱,以选取引起结构不同地震反应水平的输入地震动。本文结果和结论可供结构弹塑性时程分析选取合适的输入地震动参考。 相似文献
8.
《地震工程与工程振动》2016,(4)
基于性态的结构抗震设计中的强度折减系数是确定结构非弹性反应谱的重要依据。本文研究主余震序列型地震作用下单自由度体系考虑损伤的强度折减系数谱。首先收集主余震实测记录并按中国抗震规范要求进行场地类别划分,对余震峰值进行调幅后进行单自由度结构弹塑性动力时程分析,研究了结构周期、延性系数、损伤指数、余震作用等因素对强度折减系数需求的影响。结果表明余震对强度折减系数的影响显著,考虑累积损伤的强度折减系数(R_D)是基于位移延性的强度折减系数(R_μ)的0.6至0.9倍。最后,经过统计平均和回归分析,建立了平均强度折减系数谱的简化公式。 相似文献
9.
本文旨在分析脉冲型地震动中不同频率的地震动分量对于原始地震动幅值及其非弹性反应谱的影响.首先以近期12次大地震的53条典型脉冲型地震动为数据基础,基于多尺度分解方法获取脉冲型地震动中的高频分量和低频分量.为与传统方法对比,本文获取了能够表征地震动脉冲特性的卓越分量及滤除卓越分量的剩余分量.然后对比分析原始地震动和4种地震动分量的幅值特征和非弹性反应谱的特性,以讨论地震动分量对原始地震动幅值参数及其非弹性反应谱的影响.最后结合简谐地震动模型和地震动分量的性质,讨论脉冲型地震动非弹性反应谱诸多特征的产生原因.分析发现,低频分量不仅是控制脉冲型地震动速度和位移幅值的主要因素,其对原始地震动的加速度幅值也具有不可忽略的影响.低频分量也是导致脉冲型地震动非弹性位移比谱偏大以及强度折减系数谱偏小的直接原因,从而造成结构在脉冲型地震动作用下需要具有更大的非弹性位移以及更高的强度需求. 相似文献
10.
弹塑性反应谱法中,强度折减系数、延性系数、周期之间的关系模型(R—μ—T关系)是影响计算结果的一个重要参数。各国学者考虑不同地震动记录、滞回模型、场地土条件、阻尼比等参数,提出了不同的模型,但在场地特征对关系影响上存在不同认识。本文按考虑我国场地土类型的模型,分别进行了某高层混合结构在设防7度、7.5度、8度、8.5度、9度下的弹塑性反应谱计算,得到了一系列结构最大层间位移角,并与增量动力分析(IDA)的结果进行了对比。分析表明,考虑我国场地土类型的高层混合结构弹塑性反应谱计算结果与IDA分析50%均值曲线吻合较好。本文计算结果可为弹塑性反应谱法在复杂高层结构中的应用提供基础。 相似文献
11.
Performance based design of structure requires a reasonably accurate prediction of displacement or ductility demand. Generally, displacement demand of structure is estimated assuming fixity at base and considering base motion in one direction. In reality, ground motions occur in two orthogonal directions simultaneously resulting in bidirectional interaction in inelastic range, and soil–structure interaction (SSI) may change structural response too. Present study is an attempt to develop insight on the influence of bi-directional interaction and soil–pile raft–structure interaction for predicting the inelastic response of soil–pile raft–structure system in a more reasonably accurate manner. A recently developed hysteresis model capable to simulate biaxial interaction between deformations in two principal directions of any structural member under two orthogonal components of ground motion has been used. This study primarily shows that a considerable change may occur in inelastic demand of structures due to the combined effect of such phenomena. 相似文献
12.
Rotation-invariant measures of earthquake response spectra 总被引:1,自引:1,他引:0
A new procedure for combining the response spectra of two horizontal components of recorded ground motion is presented. The presented formulation accounts for different orientations of accelerometer sensors and derives the maximum and the expected (mean) horizontal response spectra at a site, both of which are invariant to rotation of sensor axes. The maximum response spectrum is derived as the peak resultant response of single degree of freedom oscillators subjected to the as-recorded ground acceleration. The expected spectrum is derived by projecting the displacement response (due to as-recorded motion) along two orthogonal axes to a principal axes in which the displacement responses are uncorrelated. This property is used to formulate an approximation for the expected response spectrum over all possible sensor orientations. A large set of accelerometric data from Europe and the Middle East is used to demonstrate the applicability of the proposed response spectral measures. 相似文献
13.
A procedure for the determination of inelastic design spectra (for strength, displacement, hysteretic and input energy) for systems with a prescribed ductility factor has been developed. All the spectra are consistent (interrelated and based on the same assumptions). This is the first of two companion papers which deals with the ‘classical’ structural parameters: strength and displacement. The input data are the characteristics of the expected ground motion in terms of a smooth elastic pseudo-acceleration spectrum. Simple, approximate expressions for the strength reduction factor R are proposed. The value of R depends on the natural period of the system, the prescribed ductility factor, the hysteretic behaviour, damping and ground motion. Fairly accurate approximations to the inelastic spectra for strength and displacement can be derived from the elastic spectrum using the proposed values for R. 相似文献
14.
In this paper, a stochastic approach for obtaining damage-based inelastic seismic spectra is proposed. The Park and Ang damage model, which includes displacement ductility and hysteretic energy, is adopted to take into account the cumulative damage phenomenon in structural systems under strong ground motions. Differently from previous studies in this field, damage-based seismic spectra are obtained by means of peak theory of stochastic processes. The following stochastic inelastic seismic spectra are constructed and then analyzed: damage-based displacement and acceleration inelastic spectra, damage-based response modification factor spectra, damage-based yield strength demand spectra and damage-based inelastic displacement ratio spectra. 相似文献
15.
In two companion papers a simplified non‐linear analysis procedure for infilled reinforced concrete frames is introduced. In this paper a simple relation between strength reduction factor, ductility and period (R–µ–T relation) is presented. It is intended to be used for the determination of inelastic displacement ratios and of inelastic spectra in conjunction with idealized elastic spectra. The R–µ–T relation was developed from results of an extensive parametric study employing a SDOF mathematical model composed of structural elements representing the frame and infill. The structural parameters, used in the proposed R–µ–T relation, in addition to the parameters used in a usual (e.g. elasto‐plastic) system, are ductility at the beginning of strength degradation, and the reduction of strength after the failure of the infills. Formulae depend also on the corner periods of the elastic spectrum. The proposed equations were validated by comparing results in terms of the reduction factors, inelastic displacement ratios, and inelastic spectra in the acceleration–displacement format, with those obtained by non‐linear dynamic analyses for three sets of recorded and semi‐artificial ground motions. A new approach was used for generating semi‐artificial ground motions compatible with the target spectrum. This approach preserves the basic characteristics of individual ground motions, whereas the mean spectrum of the whole ground motion set fits the target spectrum excellently. In the parametric study, the R–µ–T relation was determined by assuming a constant reduction factor, while the corresponding ductility was calculated for different ground motions. The mean values proved to be noticeably different from the mean values determined based on a constant ductility approach, while the median values determined by the different procedures were between the two means. The approach employed in the study yields a R–µ–T relation which is conservative both for design and performance assessment (compared with a relation based on median values). Copyright © 2004 John Wiley & Sons, Ltd. 相似文献
16.
Eduardo Miranda 《地震工程与结构动力学》1993,22(12):1031-1046
This paper presents a probabilistic approach to the estimation of lateral strengths required to provide an adequate control of inelastic deformations in structures during severe earthquake ground motions. In contrast to a deterministic approach, the approach presented herein accounts explicitly for the variability of the response of non-linear systems due to the inherent uncertainties in the intensity and characteristics of the input excitation by considering the probability distribution of maximum inelastic strength demands. This study is based on the computation of non-linear strength demands of single-degree-of-freedom (SDOF) systems experiencing different levels of inelastic deformation when subjected to 124 recorded earthquake ground motions. Using empirical cumulative distribution functions site-dependent probabilistic non-linear spectra were computed for six probabilities of exceedance of different levels of inelastic deformation. It is concluded that the lateral strength required to control displacement ductility demands is significantly affected by the maximum tolerable inelastic deformation, the system's period of vibration, the local site conditions and the level of risk in exceeding the maximum tolerable deformations. 相似文献
17.
This paper presents a statistical study of the kinematic soil-foundation-structure interaction effects on the maximum inelastic
deformation demands of structures. Discussed here is the inelastic displacement ratio defined as the maximum inelastic displacement
demands of structures subjected to foundation input motions divide by those of structures subjected to free-field ground motions.
The displacement ratio is computed for a wide period range of elasto-plastic single-degree-of-freedom (SDOF) systems with
various levels of lateral strength ratios and with different sizes of foundations. Seventy-two earthquake ground motions recorded
on firm soil with average shear wave velocities between 180 m/s and 360 m/s are adopted. The effects of period of vibration,
level of lateral yielding strength and dimension of foundations are investigated. The results show that kinematic interaction
will reduce the maximum inelastic displacement demands of structures, especially for systems with short periods of vibration,
and the larger the foundation size the smaller the maximum inelastic displacement becomes. In addition, the inelastic displacement
ratio is nearly not affected by the strength ratio of structures for systems with periods of vibration greater than about
0.3 s and with strength ratios smaller than about 3.0. Expressions obtained from nonlinear regression analyses are also proposed
for estimating the effects of kinematic soil-foundation-structure interaction from the maximum deformation demand of the inelastic
system subjected to free-field ground motions. 相似文献
18.
Reinforced concrete bridge columns exhibit complex hysteretic behavior owing to combined action of shear, bending moment, and axial force under multi‐directional seismic shakings. The inelastic displacement of columns can be increased by shear–flexure interaction (SFI). This paper develops a simple yet reliable demand model for estimating the inelastic displacement and ductility based on the nonlinear time history analyses of 24 full‐size columns subject to a suite of near‐fault ground motions. A coupled hysteretic model is used to simulate the shear‐flexure interactive (SFI) behavior of columns and the accumulated material damage during loading reversals, including pinching, strength deterioration, and stiffness softening. Guided by rigorous dimensional analysis, the inelastic displacement responses of bridge columns are presented in dimensionless form showing remarkable order. A dimensionless nonlinearity index is derived taking into account of the column strength, ground motion amplitude, and softening or hardening post‐yield behavior. Strong correlation is revealed between the normalized inelastic displacement and the dimensionless structure‐to‐pulse frequency, the dimensionless nonlinearity index as well as the aspect ratio. Two regressive equations for displacement and ductility demands are proposed and validated against the simulation results. The SFI effects are discussed and included explicitly through the aspect ratio in the proposed model. This study offers a new way to realistically predict the inelastic displacement of columns directly from structural and ground motion characteristics. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献