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深厚液化土地基的抗液化综合措施 总被引:3,自引:0,他引:3
广州海珠粮库筒了地基中存在厚度超过10m的严重液化土,强烈地震可能引起大面积土层液化,使场地地基失效。采用桩基法(独立承台灌注桩、预制桩、砂石桩)、换填土法、密实土法(强夯结合(先桩后夯、先夯后桩)、刚柔相济的长短桩(预制桩加碎石桩)结合的抗液化综合措施。 相似文献
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最近20年地震中场地液化现象的回顾与土体液化可能性的评价准则 总被引:1,自引:0,他引:1
回顾了1994年美国Northridge地震、1995年日本阪神地震、1999年土耳其Kocaeli地震、1999年台湾集集地震、2008年中国汶川地震、2010年智利Maule地震、2010~2011新西兰Darfield地震及余震、2011年东日本地震中大量的、不同类型的液化实例调查与研究,发现这些地震的液化具有以下特点:(1)罕见的特大地震(Mw9.0)使远离震中300~400 km的新近人工填土发生严重的大规模液化;(2)特大地震(Ms8.0、Mw8.8)使远离震中的低烈度Ⅴ~Ⅵ度地区发生严重液化;(3)海岸、河岸附近地区的新近沉积冲积、湖积土,填筑时间不到50年的含细粒、砂砾人工填土,容易发生严重液化;(4)天然的砂砾土层液化发生严重液化;(5)发生了深达20 m的土层液化现象;(6)松散土层液化后可以恢复到震前状态并再次发生液化;(7)高细粒(粒径≤75 ?m)含量≥50%或高黏粒(粒径≤5 ?m)含量≥25%的低-中塑性土严重液化,对介于类砂土与类黏土之间的过渡性态土,有时地表未见液化现象;(8)液化土层的深度较深或厚度较小时,容易出现地面裂缝而无喷砂现象;有较厚的上覆非液化土层时,场地液化不一定伴随地表破坏。液化实例证明,第四系晚更新世Q3地层可以发生严重液化;黏粒含量不是评价细粒土液化可能性的一个可靠指标;低液限、高含水率的细粒土易发生液化,采用塑性指数PI、含水率wc与液限LL之比作为细粒土液化可能性评价的指标是适宜的。综合Boulanger和Idriss、Bray和Sincio、Seed和Cetin等的液化实例调查与室内试验研究成果,建议细粒土液化可能性的评价准则如下:PI <12且wc/LL>0.85的土为易液化土,12<PI≤20和/wc/LL≥0.80的土为可液化土;PI >20或wc/LL<0.80的土为不液化土。 相似文献
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淞江古河道内地基土由饱和、呈松散—稍密状态亚砂土夹轻亚粘土、粉细砂等组成,各工点组成的地基土类型、反映在地震烈度7°时极易产生液化。产生严重液化深度主要在埋深3~10米,埋深10米以下往往仅具轻微液化。故于古河道内拟建建筑物,应重视地基土的液化判别工作,以利于地基土的处理。 相似文献
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建筑场地地震液化危害评价及地基处理 总被引:5,自引:2,他引:3
本文分析了地基失稳,计算震陷值及差异震陷等地基失效形式和液化土层的隔震作用,研究了液化指数、地基失效、液化土层隔震与多层房屋震害的关系,根据液化土的双重作用原理划分了液化危害等级,并提出了建筑场地地震液化危害评价方法和按小震不坏,中震可修,大震不倒的抗液化处理原则。 相似文献
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地基液化是高地震烈度区影响地基稳定性的重要因素之一,是引起构筑物破坏的主要形式。通过工程实例说明采用强夯法处理可液化地基,可有效消除液化,提高地基承载力。 相似文献
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砂土液化判别方法可靠性评价 总被引:7,自引:3,他引:7
在进行液化评价简化法与规范液化判别方法对比基础上,利用液化概率的对数回归方程,讨论了规范液化判别方法的可靠性。研究结果表明,我国规范液化判别方法其液化概率变动较大,对于烈度 Ⅶ 度,规范法的液化概率在0.17~0.42间,小于简化法概率0.36~0.43,偏保守。对于烈度 Ⅷ 度和 Ⅸ 度近地表场地,规范法的液化概率高达0.65~0.70,远远高于简化法的液化概率,安全裕度不够。对于含粘粒土质液化评价,规范方法的液化概率总体上都较简化法高,特别是烈度Ⅷ度高粘粒含量其液化概率为0.9。 相似文献
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通过对取自2013年岷县漳县Ms6.6地震影响区8个灾后重建安置点的黄土进行室内动、静三轴试验,研究了极震区2个灾后重建场地黄土的动、静力学特性,分析了地震影响区内3个灾后重建安置场地的黄土斜坡稳定性和5个场地黄土的震陷性;并结合安置点的地形地貌特点,对灾后重建场地潜在黄土地震地质灾害进行了预测。结果表明:极震区黄土在静力作用下具有明显的应力强化特性,在循环动荷载作用下具有刚度迅速衰减和粘滞性急剧增强的特征;MX-2和MX-3重建场地的斜坡在地震作用下存在失稳的可能;Ⅷ度以上地震作用下,MX-1、ZX-1、LT-1和LX-1场地存在产生不同破坏等级震陷灾害的风险;Ⅷ度以上地震作用下MX-1场地的黄土可产生液化,存在导致山体液化滑坡、泥流以及建构筑物地基失稳和不均匀沉降等地震灾害的风险。 相似文献
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2008年5·12特大地震中,位于甘肃省清水县郭川乡的田川村发生了饱和黄土的液化滑移灾害。本文首先在对田川场地进行考察的基础上,综合田川在汶川地震中的震害情况以及滑移区的地形条件,将该地区在汶川地震中的烈度进行了修正。其次对田川黄土进行了物性指标测试以及室内动三轴液化试验,根据试验结果,综合考虑产生液化所需的场地及土性条件、黄土的动强度和液化特性,对田川黄土液化灾害进行了分析,并采用反应分析的方法对其进行了液化判定。研究结果证明了田川黄土液化的事实存在性,为低烈度区黄土液化提供了新的震害依据。
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Numerical simulation of mitigation for liquefaction-induced soil deformations in a sandy ground improved by cement grouting 总被引:4,自引:0,他引:4
This paper presents a numerical study of mitigation for liquefaction during earthquake loading. Analyses are carried out using
an effective stress based, fully coupled, hybrid, finite element-finite differences approach. The sandy soil behavior is described
by means of a cyclic elastoplastic constitutive model, which was developed within the framework of a nonlinear kinematic hardening
rule. In theory, the philosophies of mitigation for liquefaction can be summarized as two main concepts, i.e. prevention of
excess pore water pressure generation and reduction of liquefaction-induced deformations. This paper is primarily concerned
with the latter approach to liquefaction mitigation. Firstly, the numerical method and the analytical procedure are briefly
outlined. Subsequently, a case-history study, which includes a liquefaction mitigation technique of cement grouting for ground
improvement of a sluice gate, is conducted to illustrate the effectiveness of liquefaction countermeasures. Special emphasis
is given to the computed results of excess pore water pressures, displacements, and accelerations during the seismic excitation.
Generally, the distinctive patterns of seismic response are accurately reproduced by the numerical simulation. The proposed
numerical method is thus considered to capture the fundamental aspects of the problems investigated, and yields results for
design purposes. From the results in the case, excess pore water pressures eventually reach fully liquefied state under the
input earthquake loading and this cannot be prevented. However, liquefaction-induced lateral spreading of the foundation soils
can be effectively reduced by the liquefaction mitigation techniques.
An erratum to this article can be found at 相似文献
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2008年汶川Mw7.9地震的强地面震动在龙门山前地区造成大量的砂土液化、喷砂冒水等地震灾害现象。震后野外调查发现,砂土液化点主要分布于地下水位只有几米深的山前河流的低阶地处,以大面积砾性土液化为特征,约58%的液化点位于距北川断层20~35km的范围内。对喷水高度及喷水过程进行了详细记录,喷水高度与峰值加速度并没有明显的相关性,喷水高度异常点(2m)集中于山前断裂系统近地表投影处。汶川地震中喷水高度异常、砾性土液化的位置与山前断裂系统的吻合性说明,沉积盆地内的地质构造可能在砂土液化强度和与震动相关的地震灾害方面起到促进作用,所以在类似的地质和水文环境中,除主震的断层错动外,应考虑地质构造在地震危险性评估和建筑物抗震设计中的重要作用。 相似文献
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The paper provides a new analysis procedure for the assessment of the lateral response of isolated piles/drilled shafts in saturated sands as liquefaction and lateral soil spread develop in response to dynamic loading such as that generated by the earthquake shaking. The presented method accounts for: (1) the development of full liquefaction in the free-field soil that could trigger the lateral spread of the overlying crust layer; (2) the driving force exerted by the crust layer based on the interaction between the pile and the upper non-liquefied soil (crust) layer; and (3) the variation of the excess pore water pressure (i.e. post-liquefaction soil strength) in the near-field soil with the progressive pile deflection under lateral soil spread driving force. A constitutive model for fully liquefied sands under monotonic loading and undrained conditions is developed in order to predict the zone of post-liquefaction zero-strength of liquefied sand before it rebounds with the increasing soil strain in the near-field. The analytical and empirical concepts employed in the Strain Wedge (SW) model allow the modeling of such a sophisticated phenomenon of lateral soil spread that could accompany or follow the occurrence of seismic events without using modifying parameters or shape corrections to account for soil liquefaction. 相似文献
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采用组件式GIS (COMGIS)技术开发了结合BP神经网络分析模型的场地地震液化势评价系统,调用水平成层土地震反应分析程序SHAKE91实现设定地震下地震动影响场的模拟。在VB下调用Matlab神经网络工具箱来完成场地地震液化势评价模型在COMGIS系统中的模块化;利用GIS技术对评价结果,即液化势等级进行空间复合,给出场地潜在的地层液化势空间分布图。研究表明,SHAKE91应用程序在系统菜单下可直接调用,实现地震动影响场计算的模块化;BP神经网络技术应用于场地地震液化势评价中能达到较为理想的效果;系统的GIS空间分析功能可使评价结果与场地信息进行空间匹配,实现目标场地潜在地震液化势的快速评估。 相似文献
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On 25 December 1884, an earthquake of epicentral intensityI
0 = IX in the MSK scale caused great damage in a large area in the provinces of Granada and Málaga, in the south of Spain. The reports of the Spanish, Italian and French Commissions that studied the earthquake described ground phenomena in seven different sites which can be identified as soil liquefaction.By means of dynamic penetration tests carried out in the above sites, the corresponding soil profiles (based on SPT data and water table depth) were established, and the occurrence of liquefaction was proved in five out of seven of these sites. Also, the intensities at such locations and the magnitude of the earthquake were estimated.From the geotechnical data and the cyclic stress ratio induced by the earthquake, liquefaction conditions were confirmed in all the five sites which presumably liquefied. Then, possible values of the minimum ground surface accelerations necessary for the onset of liquefaction at each location were calculated. The results obtained were completed with data reported in six liquefaction case studies from Japan and the United States, from which design charts relating soil acceleration with normalized SPT values for different intensity levels were drawn.Finally, by using standard attenuation curves, the above data were translated into epicentral distances, and good agreement with the known epicentral area was found. As a result, a consistent approach for liquefaction hazard and source location problems has been developed. The proposed method combines in its formulation historical evidence and earthquake engineering techniques. 相似文献
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饱和砂土地震液化判别的可拓聚类预测方法 总被引:4,自引:0,他引:4
基于可拓学的物元模型和聚类分析原理,提出了饱和砂土地震液化判别的可拓聚类方法。选取地震烈度、震中距、砂层埋置深度、地下水位、标贯击数、平均粒径、不均匀系数和动剪应力比等8个影响因素,作为饱和砂土地震液化的评价因子,构建了经典域物元和节域物元。应用物元理论和可拓集合中的关联函数,建立预测模型,通过聚类分析得到饱和砂土地震液化的判别结果。实例研究表明,该模型能客观地反映砂土的液化规律,可拓聚类预测方法应用于饱和砂土地震液化判别是有效可行的。 相似文献
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India is prone to earthquake hazard; almost 65 % area falls in high to very high seismic zones, as per the seismic zoning map of the country. The Himalaya and the Indo-Gangetic plains are particularly vulnerable to high seismic hazard. Any major earthquake in Himalaya can cause severe destruction and multiple fatalities in urban centers located in the vicinity. Seismically induced ground motion amplification and soil liquefaction are the two main factors responsible for severe damage to the structures, especially, built on soft sedimentary environment. These are essentially governed by the size of earthquake, epicentral distance and geology of the area. Besides, lithology of the strata, i.e., sediment type, grain size and their distribution, thickness, lateral discontinuity and ground water depth, play an important role in determining the nature and degree of destruction. There has been significant advancement in our understanding and assessment of these two phenomena. However, data from past earthquakes provide valuable information which help in better estimation of ground motion amplification and soil liquefaction for evaluation of seismic risk in future and planning the mitigation strategies. In this paper, we present the case studies of past three large Indian earthquakes, i.e., 1803 Uttaranchal earthquake (Mw 7.5); 1934 Bihar–Nepal earthquake (Mw 8.1) and 2001 Bhuj earthquake (Mw 7.7) and discuss the role of soft sediments particularly, alluvial deposits in relation to the damage pattern due to amplified ground motions and soil liquefaction induced by the events. The results presented in the paper are mainly focused around the sites located on the river banks and experienced major destruction during these events. It is observed that the soft sedimentary sites located even far from earthquake epicenter, with low water saturation, experienced high ground motion amplification; while the sites with high saturation level have undergone soil liquefaction. We also discuss the need of intensifying studies related to ground motion amplification and soil liquefaction in India as these are the important inputs for detailed seismic hazard estimation. 相似文献