西安市岩土体剪切波速与土层深度关系的研究

通过对西安市3个主要地貌单元共309个钻孔剪切波速资料的分析整理,采用指数和线性拟合两种方法对测点较多的细砂、中砂、粗砂、黄土、粉质粘土、古土壤、卵石等土类的剪切波速VS与土层深度H的关系进行统计回归,得到其经验关系式;将实测剪切波速值与利用上述统计结果得到的预测值进行对比检验,两者差别不大。说明区分地貌单元和各类土层的VS与H经验关系可靠且符合当地岩土特征,可用于西安地区一般建筑的工程勘察与地震安全性评价工作。     

太原地区剪切波速的深度分布

利用太原地区２６个钻孔约５４０个剪切波速沿深度变化的实测燃料，统计给出了太原地区剪切波速沿深度变化的经验关系，据钻孔分布在不同的地貌单元，具有不同的地层特征的情况，对剪切速波沿深度变化的规律进行了分区统计，给出了分区统计结果，这些统计结果可在地场类别确定中用于估计覆盖土层的厚度，即地面至剪切波速大于５００ｍ／ｓ土层的距离。     

喀什场地土剪切波速与土层深度经验关系

在喀什市城区地震小区划工作的基础上,通过对喀什城区地貌单元划分,描述了不同地貌单元内的地层岩性,将实测剪切波速钻孔资料统计分析,运用较为常用的三种统计回归分析方法给出喀什市城区不同地貌单元不同土类剪切波速与土层深度的经验关系。结果可为喀什市城区防震减灾规划土层地震反应分析提供依据。     

山西长治市区第四系岩性及剪切波速与深度关系初探

通过对山西长治市区41个钻孔柱状和剪切波速资料的整理分析,利用剪切波速与深度的指数式经验公式,对土层剪切波速Vs与土层深度H间的关系进行统计回归。经对比检验得出,土层Vs-H统计关系符合本地岩性特征。     

和田市土层剪切波速与土层埋深关系统计分析

收集和田市土层钻孔剪切波速实测数据,按照地貌单元划分,按不同岩性分别采用线性函数模型、一元二次函数模型及幂函数模型等三种模型进行土层剪切波速与土层埋深的统计回归分析,给出拟合参数和拟合优度R2,从而得到和田市各工程地质单元各类土层剪切波速与土层埋深关系公式。并对统计回归分析结果进行了显著性检验,此基础上计算出场地覆盖层厚度计算值,将土层剪切波速预测值与实测值、覆盖层厚度计算值与实测值进行对比,验证统计回归关系式的合理性和适用性。结果表明,统计分析得到的和田市城区各工程地质地貌单元各类土层剪切波速与土层埋深关系公式较为准确可靠。     

武汉市区土体剪切波速与深度的经验关系

通过对武汉市区3个主要地质单元共8 305个剪切波速数据的分析整理,分别运用线性函数、一元二次多项式函数、指数函数对武汉市区不同地貌单元不同土类的剪切波速与深度的关系进行统计回归,得到其经验关系。结果表明,武汉市区土体剪切波速与埋深相关性比较明显;一元二次多项式函数的拟合效果最好。将实测数据与利用经验关系得到的预测值进行对比检验,两者基本吻合,可供武汉市区场地剪切波速数据缺乏时参考使用。     

华北地区剪切波速与深度之间统计关系的通用模型特征研究

剪切波速是区别土动力学和静力学的重要参数,其影响因素包括土层埋深、颗粒形状、颗粒比重、压缩模量、孔隙比、含水率和密度等,其中土层埋深对剪切波速的变化影响较大。本文搜集整理了华北地区10个城市的928个钻孔共10703个测点的剪切波速与土层埋深之间的经验统计关系,探讨华北地区剪切波速随深度变化的特征,并从岩性条件、沉积环境等方面分析其原因。通过对比分析,给出了华北地区黏性土和砂类土剪切波速随深度变化的最佳拟合经验统计关系,并进行实例验证,所得结果可为缺乏数据的区域提供一定参考。     

基于灰色关联分析回归天津市区土体剪切波速

利用天津市78个钻孔2 212组不同岩土体的剪切波速数据,分析天津地区土层剪切波速随土层深度、岩土类型等影响因素的变化规律,利用灰色关联分析方法研究上述影响因素与天津地区土层剪切波速之间的相关性,获得该区土层剪切波速各影响因素的灰色关联排序,继而得到区分岩土类型的剪切波速回归公式,利用所得公式对实际钻孔不同深度剪切波速进行预测,并基于实测结果对预测结果进行分析。在天津地区,应综合利用岩土类型和土层深度对剪切波速进行评价。不同岩土类型、剪切波速与深度的相关性大小存在较为明显的差异,其中粘土的剪切波速和深度之间的相关性最强。同等深度条件下,由粘土到细砂粒径逐渐增大,其相应的剪切波速也逐渐增大。各类主要岩土体剪切波速与埋深之间的相关关系中多项式模型拟合精度最高,可用于天津市区主要土体剪切波速计算工作。     

西宁市区土层剪切波速随深度变化特征

通过对西宁市区67个钻孔剪切波速资料整理,采用最小二乘法进行统计回归分析,得到西宁市土层剪切波速Vs随土层埋深H的经验关系式,西宁市典型土类Vs与H的经验关系。并且通过实测剪切波速与预测剪切波速的对比,验证所得经验关系式的适用性。     

玉溪盆地浅层土层颗粒特征与剪切波速的关系研究

以玉溪盆地16个钻孔的柱状图和波速数据为基础,统计分析了具有不同颗粒特征的土层埋深与剪切波速之间的关系,给出了玉溪盆地内角砾、砾石、圆砾、砾砂、细砂和淤泥质黏土等土层在80 m深度范围内深度与剪切波速的经验关系.通过分析不同颗粒大小、不同磨圆程度土层剪切波速特征,认为土层的波速特征与其形成时所处的沉积环境有一定的关系,并以玉溪盆地浅层土层为例,给出了一种根据具有明显颗粒特征土层估算未测波速钻孔的等效剪切波速的方法.      

杭州市典型土层剪切波速与埋深间的关系分析

基于杭州市丰富的场地钻孔剪切波速资料,采用3种常见的剪切波速与埋深回归分析模型,分析杭州地区5类常规土在场地分类和场地未分类情况下的最优拟合公式和预测范围,并对推荐模型进行可靠性验证,对常规粉质粘土和粉砂进行地区差异性分析。研究结果表明:本文推荐的剪切波速与埋深关系公式具有良好的可靠性;地区、岩土类型和预测深度均对剪切波速与埋深关系模型的可靠性产生显著影响,故应用时应优先选用本地区统计模型,如若未有,则需根据已有资料,对选用模型进行岩土类型和适应预测深度范围验证,以保证所选模型的可靠性;受地区、岩土类型和预测深度的影响,考虑场地分类并不一定提高统计模型的预测精度,在实际工程应用中具有不确定性。     

金银岛岩土台阵原位剪切波速剖面评估

土层的剪切波速是描述土动力学特性的重要参数之一。利用金银岛岩土台阵记录的8次浅源地方震的弱震动数据,使用解卷积的地震干涉测量法识别的剪切波走时,评估了该台阵两个水平方向的原位剪切波速剖面。结果表明:在44.2m深度以上,估计与实测的平均剪切波速剖面基本一致,而在44.2m到103.6m深度范围前者大于后者;本研究估计的平均剪切波速剖面比MEHTA等（2007）估计的平均剪切波速剖面更接近实测结果,在44.2m到103.6m深度范围,本研究估计的平均剪切波速与MEHTA等（2007）估计的平均剪切波速相近,二者均大于实测的平均剪切波速。     

土层剪切波速测试中的不确定性对场地地震动参数的影响分析——以Ⅲ类场地为例

本文选取山东地区2个Ⅲ类场地的工程地质勘探及土层剪切波速等资料,将土层厚度按5个深度段,每个分段给出了4个土层剪切波速的改变量,通过改变不同深度段土层剪切波速,建立了19种土层地震反应分析模型,分析了不同深度段,不同概率水平下土层剪切波速的变化对场地地震动参数的影响。研究表明,不同深度段土层剪切波速的变化对场地地震动参数的影响有差异。具体表现为,土层剪切波速的改变在1—10m、11—40m和地震输入界面处三个深度段对地震动加速度峰值影响较大;其中,41—70m和71—100m两个深度段剪切波速的改变对地震动加速度峰值影响小;在土层深度1—10m时,剪切波速降低,峰值变大,剪切波速的改变与峰值的改变呈负相关;在其它深度段,剪切波速降低,峰值变小,剪切波速的改变与峰值的改变呈正相关。剪切波速的改变在1—10m和11—40m两个深度段对地震加速度反应谱影响较大;在41—70m、71—100m和地震输入界面三个深度段对地震加速度反应谱影响很小。     

The porosity of saturated shallow sediments from seismic compressional and shear wave velocities

This study devises a new analytical relationship to determine the porosity of water-saturated soils at shallow depth using seismic compressional and shear wave velocities. Seismic refraction surveys together with soil sample collection were performed in selected areas containing water-saturated clay–silt, sand and gravely soils. Classification of clay–silt, sand and gravel dense soils provided the coefficient of experimental equation between the data sets, namely, Poisson's ratio, shear modulus and porosity values. This study presents a new analytical relationship between Poisson's ratio and shear modulus values, which are obtained from seismic velocities and porosity values of water-saturated material computed from water content and grain densities, which are determined by laboratory analysis of disturbed samples. The analytical relationship between data sets indicates that when the shear modulus of water-saturated loose soil increases, porosity decreases logarithmically. If shear modulus increases in dense or solid saturated soils, porosity decreases linearly.     

APPLICATION AND STATISTICAL ANALYSIS OF RELATIONSHIP BETWEEN SHEAR WAVE VELOCITY AND DEPTH OF SOIL-LAYERS

The shear wave velocity is one of the important parameters in seismic engineering.The common mathematical models of relationship between shear wave velocity and depth of soil-layers are linear function model,quadratic function model,power function model,cubic function model,and quartic function model.It is generally believed that the regression formulae based on aforementioned mathematical models are mainly used for preliminary estimation of the local shear wave velocity.In order to increase the value of test data of wave speed in boreholes,the calculation formulae for the thickness of ground cover layer are derived based on the aforementioned mathematical models and their fitting parameters.The calculation formulae for the mean shear wave velocity of soil-layers are derived by integral mean value theorem.Accordingly,the calculation formulae for the equivalent shear wave velocity of soil-layers are derived.The calculation formulae for the depth of reflective waves in time-depth conversion of the reflection seismic exploration are derived.Through the statistical analysis of test data of shear wave velocity of soil layers in Changyuan County,Henan Province,regression formulae and their fitting parameters of aforementioned mathematical models are obtained.The results show that in the determination of the quality of these regression formulae and their fitting parameters,the adjusted R-square,root mean square error and residual error,the matching on the statistical range between the geometry of function of mathematical models used and the scattergram of the measured data,the application purpose and the simplicity of the regression formulae should be considered.With the aforementioned new formulae,the results show that the calculated values of equivalent shear wave velocity of soil-layers and thickness of ground cover layer meet the engineering needs.The steps for statistics and applications of the relationship between shear wave velocity and depth of soil-layers for a new area are as follows:(1) Analyze the relevant data about the site such as the drilling and wave speed test data,etc.and divide the site into seismic engineering geological units;(2) In a single seismic engineering geological unit,make statistical analysis of the data of borehole wave speed test,comprehensively identify and select mathematical models and their fitting parameters of the relationship between shear wave velocity and depth of soil-layers;(3) Substitute the selected fitting parameters into the formulae,based on their mathematical models for the thickness of ground cover layer,or the equivalent shear wave velocity of soil-layers,or the depth of reflective wave,then the thickness of ground covering layer,equivalent shear wave velocity,and depth of reflective wave are obtained.     

Application of passive source surface-wave method in site engineering seismic survey

Site engineering seismic survey provides basic data for seismic effect analysis. As an important parameter of soil, shear-wave velocity is usually obtained through wave velocity testing in borehole. In this paper, the passive source surface-wave method is introduced into the site engineering seismic survey and practically applied in an engineering site of Shijingshan District. By recording the ubiquitous weak vibration on the earth surface, extract the dispersion curve from the surface-wave components using the SPAC method and obtain the shear-wave velocity structure from inversion. Over the depth of 42 m underground, it totally consists of five layers with interface depth of 3.31, 4.50, 7.23, 17.41, and 42.00 m; and shear-wave velocity of 144.0, 198.3, 339.4, 744.2, and 903.7 m/s, respectively. The inversion result is used to evaluate site classification, determine the maximum shear modulus of soil, provide basis for further seismic hazard analysis and site assessment or site zoning, etc. The result shows that the passive source surface-wave method is feasible in the site engineering seismic survey and can replace boreholes, shorten survey period, and reduce engineering cost to some extent.     

Site-dependent shear-wave velocity equations versus depth in California and Japan

Shear-wave velocity of the near-surface ground is an important soil property in earthquake and civil engineering. Using the data from 643 boreholes from the KiK-net in Japan and 135 boreholes from California where the shear-wave velocity profile reaches at least 30 m, firstly, we classify sites by building code, then build site-dependent relationships between travel time and depth by regression utilizing the logarithmic model and power-law model, lastly, we get shear-wave velocity equations versus depth based on the mathematical relationship between travel time and velocity. The results show that: (1) the travel time is strongly correlated with depth, and the Pearson correlation coefficients range between 0.867 and 0.978. (2) there is a certain difference between linear velocity equations and power-law velocity equations, and the power-lower equations are generally more close to measured data than linear equations except for class E in Japan and class D in California. (3) the velocities are similar at the sites of each class for different regions but that the gradient of velocity with depth vary between different regions.