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1.
采用等效线性方法考虑土的动力非线性特性,利用一维波动模型分析了深软场地的地震反应特性,结果表明,与输入苏州人工地震波时的计算结果相比,大地震远场地震动作用时,深软场地的地表水平向峰值加速度明显增大,规准反应谱的特征周期值显著增大,地表设计地震动的水平地震影响系数值明显增大,且两者的差异随输入地震动峰值加速度的增大而增大;当土层剪切波速的变异性由+10%变化到-10%时,地表水平地震影响系数曲线平台值有降低的趋势,规准反应谱的特征周期略有增大,且-10%的变异性对水平地震影响系数的影响要比+10%的变异性的影响显著;土体动剪切模量比和阻尼比均有变异时对地表设计地震动参数的影响较大,且土的阻尼比由-2δ到+2δ变异时,地表水平向峰值加速度和地震影响系数平台值有减小趋势。 相似文献
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针对新型核电工程结构AP1000核岛结构设计地基中的5类非坚硬岩场地,即硬岩场地、软岩场地、上限软-中等土场地、软-中等土场地和软土场地,采用一维土层场地模型开展场地土和计算基底条件对设计地震动影响计算分析。分析中,场地模型的计算基底剪切波速分别取为700、1 100、2 438 m/s,计算基底输入地震动分别选择基于核电建设相关技术文件和规范规定的反应谱RG1.60谱、AP1000谱和HAD101/01谱(5个阻尼比)合成的人工地震动时程。计算分析表明:非坚硬岩场地会导致场地地震动峰值加速度及频谱特性显著变化,场地越软影响程度越显著;除软土场地外,场地对地震动峰值加速度和反应谱的影响均为放大作用,软土场地对地震动较低频段反应谱有放大作用,但对峰值加速度和较高频段反应谱具有强烈的减小作用;对于各类场地,计算基底及其剪切波速的变化均会导致地表地震动峰值及频谱特性明显甚至显著变化,其影响程度与计算基底剪切波速成正比;随着场地由硬变软,计算基底剪切波速的变化对场地地震动的影响程度大为减小,至软土场地几乎不产生影响。考虑到场地类型及计算基底选取对场地地震动的显著影响,我国核电厂建设引用AP1000标准设计时应合理分析场地的适宜性。 相似文献
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建筑场地的不同类别反映不同场地条件对基岩地震震动的综合放大效应,建筑场地类别是根据土层等效剪切波速和覆盖层厚度进行划分的。这里介绍了单孔法波速测试在计算土层等效剪切波速度,划分建筑场地类别上的应用,以及通过对宿州市区40个建筑场地的201个土层等效剪切波速数据Vse20和场地类别划分结果进行统计分析、研究,得出该区域类似地层条件的土层等效剪切波速近似呈正态分布特征,估算范围在195.89m/s~222.46 m/s,推测建筑场地类别为Ⅲ类。 相似文献
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地震基岩深度和土体动力本构模型的选取对核岛场地地震效应评价结果的合理性具有重要影响。以拟建某沿海核电厂深度470 m沉积土夹火山岩层场地的3个钻孔剖面为研究对象,采用一维等效线性波传分析(ELA)法、基于Matasovic本构模型和Davidenkov-Chen-Zhao(DCZ)本构模型的一维非线性分析(NLA)法,选取不同剪切波速的5个岩土层作为地震基岩,研究了输入地震动特性、地震基岩深度和土体动力本构模型的选取对巨厚沉积土夹火山岩层场地非线性地震反应特性的影响。结果表明:(1)以浅层硬岩夹层或深部土层作为地震基岩,NLA法计算的5%阻尼比的地表谱加速度SA的短周期部分较之ELA法的计算值大,但两者计算的地表SA谱的长周期部分几乎一致;(2)基于Matasovic模型和DCZ模型的NLA法计算的地表SA谱谱形和峰值加速度随深度的变化趋势基本一致;(3)从NLA法计算的地表峰值加速度和累积绝对速度而言,以剪切波速约2 500 m/s的浅层硬岩夹层作为地震基岩是适宜的。 相似文献
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强震动作用下场地土的非线性对地震动反应特征影响明显。场地土的非线性效应首先是由岩土工程学家在室内试验中发现的,继而地震学家在强震动记录分析中亦发现了场地土的非线性效应。一般来讲,随着地震动输入强度增加,场地土非线性效应越明显。但对于不同场地类型,相同地震动水平作用下,场地土非线性效应是不同的。针对这一问题,选择了几个典型场地,采用等效线性化方法分析了不同地震动强度作用下各类场地土的非线性效应,并提出了一种以场地等效剪切波速随地震动输入水平变化为依据的场地土非线性效应确定方法,且定义当等效剪切波速变化率不足20%时,场地地震反应分析可不计入场地土的非线性效应。 相似文献
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波速测试技术是地震勘探方法之一,也是一种简便、快速、准确的原位测试技术。它通过获取的地震波在经过不同深度的岩、土层的直达波旅行时,求得纵波、剪切波波速,进而通过弹性波理论,计算出岩、土层动弹性力学参数,同时也可以根据剪切波的波速,来划分场地土类型和建筑场地类别,以及计算卓越周期,这些参数可以为场地抗震设计及地震安全性评价提供依据。这里简述了波速测试技术的工作原理和野外实测技术,以及数据处理和资料解释全过程,并且结合某一建筑场地的实例,说明了波速测试技术在场地抗震评价中的应用及其效果。 相似文献
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上海软土场地三维非线性地震反应分析 总被引:1,自引:0,他引:1
考虑土的非线性,采用弹塑性边界面模型,对上海软土场地进行三维地震反应分析。利用多维地震动作用下的水平地层弹塑性动力反应分析程序,以具有水平和垂直三向完整加速度记录的Taft波作为地震输入,对比分析单向和多向地震输入场地水平和竖向地震反应特征,并分析不同强度地震动输入下竖向和水平加速度峰值比特征及地下水位变化对场地土层地震反应特征的影响。计算分析表明,竖向与水平向地震反应特征有较大差异;与水平单向地震输入相比,三向地震输入场地土层放大效应明显增大;地下水位上升对水平向和竖向峰值加速度的放大效应影响差异显著,地下水位上升,地表水平峰值加速度放大效应增大,竖向峰值加速度放大效应减小,研究结果对上海地区的工程抗震设计具有参考作用。 相似文献
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以福建省泉州市区和福州市区场地土的动力特性和地脉动频谱结构为研究对象,通过对这两个地区的地脉动信号的频谱分析获得频谱结构特征,由此来深入研究该地区岩土的动力特性及场地土层的地脉动动力响应。通过场地脉动的测试,利用快速傅立叶变换(FFT)方法对观测到的地脉动信号进行频谱分析。根据实际观测资料研究了地脉动频谱结构特征及场地土对地脉动的频率响应的特性。研究不同地基土层构造与地脉动的频率依赖以及频率选择作用。结果表明,地脉动的频谱特性与场地覆盖层厚度和地基土刚度的变化密切相关;覆盖层厚度是影响地脉动卓越周期的重要原因,其中软土层对地脉动的卓越周期有一定的放大作用。 相似文献
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Use of Surface Waves in Statistical Correlations of Shear Wave Velocity and Penetration Resistance of Chennai Soils 总被引:1,自引:0,他引:1
R. Uma Maheswari A. Boominathan G. R. Dodagoudar 《Geotechnical and Geological Engineering》2010,28(2):119-137
Shear wave velocity (V
s) is one of the most important input parameter to represent the stiffness of the soil layers. It is preferable to measure
V
s by in situ wave propagation tests, however it is often not economically feasible to perform the tests at all locations. Hence,
a reliable correlation between V
s and standard penetration test blow counts (SPT-N) would be a considerable advantage. This paper presents the development
of empirical correlations between V
s and SPT-N value for different categories of soil in Chennai city characterized by complex variation of soil conditions. The
extensive shear wave velocity measurement was carried out using Multichannel Analysis of Surface Waves (MASW) technique at
the sites where the SPT-N values are available. The bender element test is performed to compare the field MASW test results
for clayey soils. The correlations between shear wave velocity and SPT-N with and without energy corrections were developed
for three categories of soil: all soils, sand and clay. The proposed correlations between uncorrected and energy corrected
SPT-N were compared with regression equations proposed by various other investigators and found that the developed correlations
exhibit good prediction performance. The proposed uncorrected and energy corrected SPT-N relationships show a slight variation
in the statistical analysis indicating that both the uncorrected and energy corrected correlations can predict shear wave
velocity with equal accuracy. It is also found that the soil type has a little effect on these correlations below SPT-N value
of about 10. 相似文献
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Empirical correlation between standard penetration resistance (SPT-N) and shear wave velocity measured by seismic downhole techniques are prepared of the alluvial soil of quaternary age for the Kanpur city. The Kanpur city is having seismic threat from Himalaya and it falls in seismic zone III according to seismic zones of India. Standard penetration test as well seismic downhole test has been carried out up to 30 m at twelve different locations of Kanpur city. The measured SPT-N values and shear wave velocity values are used to develop empirical correlation between SPT-N and shear wave velocity. The proposed correlations have been compared with the existing regression equations by various other investigators. It is found that the proposed correlation exhibit good performance (10 % error bar). Also the measured shear wave velocity has been used to prepare spatially distributed contour map of 50, 75 and 100 m/s using ArcGIS-9 software. It is observed that the shear wave velocity values for the northern part of Kanpur city vary from 125 to 825 m/s. In southern part, it is varying from 125 to 500 m/s where as in the central part of the city the shear wave velocity varies from 125 to 375 m/s. The eastern part of the city also shows some variation in shear wave velocity which ranges from 250 to 625 m/s. The western part of the city shows the variation of shear wave velocity from ≤125 to 500 m/s. The soil type of the study area are classified as per NEHRP and new Italian O.P.M.C classification system as B, C and D type soil with having site period of 0.1–0.9 s and Poisson’s ratio varying from 0.1 to 0.4. 相似文献
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Geologic site conditions and site coefficients for estimating earthquake ground motions in the inland areas of Korea 总被引:3,自引:0,他引:3
Site characterization and site-specific ground response analyses were conducted at two representative inland areas in Korea. In situ tests included 25 boring investigations, 7 crosshole tests, 18 downhole tests and 41 SASW tests, and in the laboratory, resonant column tests were performed. The soil deposits in Korea, which were shallower and stiffer than those in the western US, were examined. The fundamental site periods were distributed in the narrow band ranging from 0.1 to 0.4 s. Most sites were designated as site classes C and D based on the mean shear wave velocity of the upper 30 m from the current Korean seismic design guide. Based on the ratio of the acceleration response spectra of ground surface to rock-outcrop, short-period (0.1–0.5 s) site coefficient, Fa ranged from 1.0 to 2.7, and mid-period (0.4–2.0 s) site coefficient, Fv ranged from 1.0 to 1.6, regardless of the input rock outcrop acceleration levels of 0.05 and 0.14 g. The site coefficients specified in the Korean seismic design guide, which is similar to NEHRP provisions and UBC, underestimate the ground motion in the short-period band and overestimate the ground motion in the mid-period band. These differences can be explained by the differences in the depth to bedrock and the soil stiffness profile between Korea and western US. Also, the site coefficients should be re-evaluated accounting for the local geologic conditions on the Korean peninsula. 相似文献
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Abbas Abbaszadeh Shahri Katayoun Behzadafshar Roshanak Rajablou 《Arabian Journal of Geosciences》2013,6(3):881-892
The seismic response of existing earth dams in Iran is important after an earthquake both to provide emergency supplies and to society as well as to ensure structural safety in engineering terms. Better seismic capacity of earth dam results in less structural damage and reduced impacts following an earthquake disaster. Indirect as well as direct costs following earthquakes have gained much attention from both the engineering and socioec onomic research communities in the last few decades. This study is a valuable tool used to study the response of geotechnical structures to infrequent or extreme events such as earthquakes. The Avaj earthquake (2002, Iran) was applied to a series of model tests which was conducted to study the response of soil profiles under seismic loading. The acceleration records at different locations within the soil bed and at its surface along with the settlement records at the surface were used to analyze the soil seismic response. A combination of several software packages with a generated visual user interface computer code by authors named as “Abbas Converter” were employed to evaluate the variation of shear modulus and damping ratio with shear strain amplitude to assess their effects on site response. The proposed method was applied to the Korzan earth dam of Hamedan province in Iran. Site response analysis using the measured shear wave velocity, estimated modulus reduction, and damping ratio as input parameters produced good agreement with the computed site response in this study. 相似文献
16.
Shear wave velocity is one of the most important input parameter in the analysis of geotechnical earthquake engineering problems,
particularly to estimate site-specific amplification factor and ground response study. Dynamic in situ tests such as spectral
analysis of surface waves (SASW) or multichannel analysis of surface waves (MASW) are very expensive. Also due to lack of
specialized personnel, these tests are generally avoided in many soil investigation programs. Worldwide, several researchers
have developed correlations between the SPT ‘N’ value and shear wave velocity ‘V
s’, which are useful for determining the dynamic soil properties. In the present study, more than 400 numbers of soil borehole
data were collected from various geotechnical investigation agencies, government engineering institutes and geotechnical laboratories
from different parts of Mumbai city, which is financial capital of India with highest population density. In this paper, an
attempt has been made to develop the correlation between the SPT ‘N’ value and shear wave velocity ‘V
s’ for various soil profile of Mumbai city and compared with other existing correlations for different cities in India. Using
Geographical Information System (GIS), a geospatial contour map of shear wave velocity profile for Mumbai city is prepared
with contour intervals of 25 and 50 m/s. The scarcity of database or maps of shear wave velocity profile for Mumbai city will
make the present geospatial contour maps extremely useful and beneficial to the designer, practitioners for seismic hazard
study involved in geotechnical earthquake engineering. 相似文献
17.
《Engineering Geology》2006,82(4):446-469
Site characterization and site-specific ground response analyses were conducted at two representative inland areas in Korea. In situ tests included 25 boring investigations, 7 crosshole tests, 18 downhole tests and 41 SASW tests, and in the laboratory, resonant column tests were performed. The soil deposits in Korea, which were shallower and stiffer than those in the western US, were examined. The fundamental site periods were distributed in the narrow band ranging from 0.1 to 0.4 s. Most sites were designated as site classes C and D based on the mean shear wave velocity of the upper 30 m from the current Korean seismic design guide. Based on the ratio of the acceleration response spectra of ground surface to rock-outcrop, short-period (0.1–0.5 s) site coefficient, Fa ranged from 1.0 to 2.7, and mid-period (0.4–2.0 s) site coefficient, Fv ranged from 1.0 to 1.6, regardless of the input rock outcrop acceleration levels of 0.05 and 0.14 g. The site coefficients specified in the Korean seismic design guide, which is similar to NEHRP provisions and UBC, underestimate the ground motion in the short-period band and overestimate the ground motion in the mid-period band. These differences can be explained by the differences in the depth to bedrock and the soil stiffness profile between Korea and western US. Also, the site coefficients should be re-evaluated accounting for the local geologic conditions on the Korean peninsula. 相似文献