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针对黄土地区现有的地震荷载作用下挡土墙土压力计算方法中的不足,进行了4个含水量和3个围压的平面应变试验,首次建立了平面应变强度参数与结构性的关系,扩展了被动状态下考虑应力主轴偏转的粘性土侧土压力系数计算公式,采用水平微分层分析方法,提出了一种地震作用下同时考虑黄土结构性和主应力轴偏转的挡土墙被动土压力计算方法。参数分析结果表明平面应变条件下地震被动土压力均大于三轴条件下,结构性土地震被动土压力大于无结构性土,墙土面有摩擦时地震被动土压力大于墙土面光滑时;地震被动土压力随水平和竖向地震加速度系数的增大而减小、随摩擦角、均布荷载、墙土摩擦角、粘聚力、构度指标的增大而增大。黄土地区地震被动土压力计算应综合考虑平面应变强度参数、结构性和墙土摩擦效应的影响。 相似文献
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海相结构性软黏土地基的沉降特性研究 总被引:2,自引:0,他引:2
通过室内试验获得了海相结构性软黏土的初始屈服面;考虑不同埋深处地基土的初始结构屈服面之间的相似性规律,应用结构性本构模型,结合工程实测数据,对海相软黏土地基土体屈服与地基沉降之间的关系进行了研究。结果表明,结构性本构模型能够较好地模拟海相结构性软黏土地基的沉降变形;结构性土地基的土体屈服是由浅及深逐步发展的,虽然存在低荷载时沉降小、高荷载时沉降大且呈非线性增大的现象,但这是渐变的过程,沉降量—时间—填土高度曲线上不能确定显著的转折点,通过观察沉降曲线的转折点来确定临界填土高度的方法将难以实现。 相似文献
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土的结构性是土颗粒空间排列和粒间粘结综合作用所表现出来的力学效应。在地震荷载作用过程中,天然土边坡的结构性参数主要体现应力和变形的共同作用,反映地震荷载作用过程中应力和变形的协调关系及结构性土的结构损伤过程(即抗剪强度参数的变化规律)。首先通过分析认为用结构性参数来定量判断地震荷载作用过程中黄土边坡的稳定性更具合理性,其物理意义更明确;其次通过分析黄土地区某一天然边坡在Ⅸ度地震烈度作用下的黄土边坡动力稳定性,验证结构性参数作为边坡稳定性分析判据的可行性,且这一方法能定量地确定边坡滑动面的位置及所对应的安全结构性参数。 相似文献
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当土体总应力状态保持不变时,基质吸力的提高是导致孔隙水排水、土样体积收缩、孔隙结构改变的根本原因,通过吸力可以将土壤收缩曲线和土水特征曲线联系起来进行比对研究。采用广义有效应力原理分析超固结土样和正常土样的失水过程,结果表明:超固结土样中存在着相应的先期固结压力的吸力值,称之为先期固结吸力ψc。当土样吸力小于ψc时,超固结土样和正常固结土样的收缩曲线、土水特征曲线不同:超固结土孔隙比随吸力提高而减小的坡度较缓,约等于土样的回弹再压缩指数,土样处于结构性收缩阶段;先期固结压力越大,土水特征曲线的进气值越高。当土样吸力高于ψc时,超固结土样和正常固结土样的收缩曲线、土水特征曲线重合。 相似文献
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《地震工程学报》2007,29(4):388-390,F0003
第1期奉献防震减灾,功绩卓著;培养德才桃李,后继有人———写在张振中、孙崇绍研究员七十华诞…………………王兰民(1)西北黄土地区河谷城市地震动参数小区划研究———以兰州为例………………………………………………………孙崇绍(3)考虑非饱和土与结构特征的黄土湿陷性讨论……………………………………………………袁中夏,王兰民,王峻(12)切比雪夫伪谱法模拟地震波场……………………………………………………………………刘鲁波,陈晓非,王彦宾(18)灵敏度在土结构性定量化研究中的应用………………………………………………………杨艳,… 相似文献
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在对89、01抗震规范中Ⅰ类场地分类界限深入的探讨的基础上,利用目前地震安全性评价中广泛使用的基于一维等效线性化波动方法研究了某市沿海地区为代表的浅层覆盖土条件下的地震动参数取值问题。针对各种情况下Ⅰ类建筑场地土,构造若干具有工程意义的典型场地剖面,合成适合本地区的基底输入地震波,计算得到浅层覆盖土条件下的场地地表加速度峰值和反应谱周期。通过对几种类型土计算结果和实际操作的分析和探讨,结果表明:放大倍数谱描述结果概念更强;复核结果偏于保守,且与抗震选用参数不兼容;当钻孔足够多时,低波速钻孔标定谱形接近高波速钻孔。 相似文献
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土-结构相互作用是一个具有重大理论意义和工程应用价值的课题。在过去四十年的研究中,在理论和实践方面已取得重大进展,但仍存在许多有待进一步研究的重要问题,发展一种有效和实用的土-结构相互作用分析方法以及了解土-结构相互作用对结构地震反应的影响就是其中的两个问题。本文在国内外土-结构相互作用研究发展现状的基础上,以钢筋混凝土高层建筑为研究对象,进行了高层建筑土-结构相互作用地震反应分析研究,为重要个体高层建筑和一般高层建筑的土-结构相互作用地震反应分析提供了多种实用的分析手段,为认识土-结构相互作用对高层建筑地震反应的影响和抗震设计方法提供了依据。 相似文献
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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
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Probabilistic analysis of soil‐structure interaction effects on the seismic performance of structures 
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下载免费PDF全文 This paper revisits the phenomenon of dynamic soil‐structure interaction (SSI) with a probabilistic approach. For this purpose, a twofold objective is pursued. First, the effect of SSI on inelastic response of the structure is studied considering the prevailing uncertainties. Second, the consequence of practicing SSI provisions of the current seismic design codes on the structural performance is investigated in a probabilistic framework. The soil‐structure system is modeled by the sub‐structure method. The uncertainty in the properties of the soil and the structure is described by random variables that are input to this model. Monte Carlo sampling analysis is employed to compute the probability distribution of the ductility demand of the structure, which is selected as the metrics for the structural performance. In each sample, a randomly generated soil‐structure system is subjected to a randomly selected and scaled ground motion. To comprehensively model the uncertainty in the ground motion, a suite of 3269 records is employed. An extensive parametric study is conducted to cover a wide range of soil‐structure systems. The results reveal the probability that SSI increases the ductility demand of structures designed based on the conventional fixed‐based assumption but built on flexible soil in reality. The results also show it is highly probable that practicing SSI provisions of modern seismic codes increase the ductility demand of the structure. Copyright © 2016 John Wiley & Sons, Ltd. 相似文献
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Soil is considered as a three-phase medium consisting of solid particles, water and air. Its behavior is very difficult to predict, especially under high rate blast loading. In this study, a new three-phase soil model for shock loading is employed to facilitate a full simulation of explosion and the subsequent stress wave propagation in soils. Upon validating the model, extended numerical calculations are carried out and the results are analyzed to demonstrate the change of characteristic parameters of the soils, the inherent distribution of the pressure on individual phases and hence the deformation mechanisms of the soils under blasting loading. Two primary deformation mechanisms exist, one is the deformation of the soil skeleton formed by the solid particles; the other is the deformation of all individual soil phases. It is found that the response of soil near the charge is dominated by the second mechanism while the first mechanism dominates in areas beyond a certain scaled range. The location of the transition zone depends primarily on the initial state of the soil. The results are useful for establishing rational and practical soil models for engineering applications concerning blasting. 相似文献
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Understanding the soil–structure interaction (SSI) mechanism is crucial in the seismic design of nuclear power plant (NPP) containment systems. Although the numerical analysis method is generally used in seismic design, there is a need for experimental verification for the reliable estimation of SSI behavior. In this study a dynamic centrifuge test was performed to simulate the SSI behavior of a Hualien large-scale seismic test (LSST) during the Chi-Chi earthquake. To simulate the soil profile and dynamic soil properties of the Hualien site, a series of resonant column (RC) tests was performed to determine the model soil preparation conditions, such as the compaction density and the ratio of soil–gravel contents. The variations in the shear wave velocity (VS) profiles of the sand, gravel, and backfill layers in the model were estimated using the RC test results. During the centrifuge test, the VS profiles of the model were evaluated using in-flight bender element tests and compared with the in-situ VS profile at Hualien. The containment building model was modeled using aluminum and the proper scaling laws. A series of dynamic centrifuge tests was performed with a 1/50 scale model using the base motion recorded during the Chi-Chi-earthquake. In the soil layer and foundation level, the centrifuge test results were similar to the LSST data in both the time and frequency domains, but there were differences in the structure owing to the complex structural response as well as the material damping difference between the concrete in the prototype and aluminum in the model. In addition, as the input base motion amplitude was increased to a maximum value of 0.4g (prototype scale), the responses of the soil and containment model were measured. This study shows the potential of utilizing dynamic centrifuge tests as an experimental modeling tool for site specific SSI analyses of soil–foundation–NPP containment system. 相似文献
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Scaling characteristics of spatial patterns of soil moisture from distributed modelling 总被引:1,自引:0,他引:1
Salvatore Manfreda Matthew F. McCabe Mauro Fiorentino Ignacio Rodríguez-Iturbe Eric F. Wood 《Advances in water resources》2007
Characterizing the spatial dynamics of soil moisture fields is a key issue in hydrology, offering an avenue to improve our understanding of complex land surface–atmosphere interactions. In this paper, the statistical structure of soil moisture patterns is examined using modelled soil moisture obtained from the North American Land Data Assimilation System (NLDAS) at 0.125° resolution. The study focuses on the vertically averaged soil moisture in the top 10 cm and 100 cm layers. The two variables display a weak dependence for lower values of surface soil moisture, with the strength of the relationship increasing with the water content of the top layer. In both cases, the variance of the soil moisture follows a power law decay as a function of the averaging area. The superficial layer shows a lower degree of spatial organization and higher temporal variability, which is reflected in rapid changes in time of the slope of the scaling functions of the soil moisture variance. Conversely, the soil moisture in the top 100 cm has lower variability in time and larger spatial correlation. The scaling of these patterns was found to be controlled by the changes in the soil water content. Results have implications for the downscaling of soil moisture to prevent model bias. 相似文献
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A comprehensive study is performed on the dynamic behavior of offshore wind turbine (OWT) structure supported on monopile foundation in clay. The system is modeled using a beam on nonlinear Winkler foundation model. Soil resistance is modeled using American Petroleum Institute based cyclic p–y and t–z curves. Dynamic analysis is carried out in time domain using finite element method considering wind and wave loads. Several parameters, such as soil–monopile–tower interaction, rotor and wave frequencies, wind and wave loading parameters, and length, diameter and thickness of monopile affecting the dynamic characteristics of OWT system and the responses are investigated. The study shows soil–monopile–tower interaction increases response of tower and monopile. Soil nonlinearity increases the system response at higher wind speed. Rotor frequency is found to have dominant role than blade passing frequency and wave frequency. Magnitude of wave load is important for design rather than resonance from wave frequency. 相似文献
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Tongxin ZHU 《国际泥沙研究》2002,17(4)
1 INTRODUCTION Soil crusting, or soil sealing, is one of the common phenomena in agricultural lands or semi-arid and arid soils. Due to the breakdown of soil aggregates by raindrops, soil surface develops a very thin, often less than a few millimeters, dense layer. Many studies indicated that such a thin layer significantly reduces infiltration capacity and increases surface runoff (i.e. McIntyre, 1958; Edward and Larson, 1969; Agassi et al., 1985; Bradford et al., 1986; Romkens et al.,… 相似文献
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This paper gives a brief presentation of the study on foundation of a residential business complex. The unfavourable geotechnical conditions of the site considered led to the need to improve the natural foundation soil. The most favourable and rational solution for providing safety and stability of structures was the combination of gravel and a sub-base. Computations were done as follows: analysis of the stress–strain state by using the parameters of the natural non-improved soil and analyses performed by using the parameters of the improved soil. The results from these analyses were used for analysis of the integral soil–structure system. Hence, complete information on the possibility for optimisation of the foundation structure was obtained. 相似文献