共查询到19条相似文献,搜索用时 140 毫秒
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本文在考虑碎石桩排水和应力集中作用的基础上分析了碎石桩处理液化地基后复合地基的抗液化能力,并与自由场液化地基的抗液化能力进行了对比,提出了一种适用于碎石桩复合地基修正“Seed简化法”,可应用标准贯入试验对液化地基的处理效果进行评价。 相似文献
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除饱和砂土液化外,饱和粉土地震液化问题也是岩土地震工程中一个重要的研究课题。饱和粉土地基的地震液化及变形可以采用多种地基加固方法防治,碎石桩技术是常用方法之一。碎石桩复合地基的抗液化效应,主要是增加桩周土体的密度、利于桩体的排水以及由桩体分担地震水平剪应力(桩体减震作用)。但由于粉土的土质特性,粉土-碎石桩复合地基的抗液化特性与砂土有着明显的差异。本文结合目前国内外碎石桩复合地基抗液化研究的最新进展,对粉土-碎石桩的密实、排水减压和减震作用做了较详细的评述,最后提出了关于碎石柱复合地基抗液化特性需要进一步研究的问题。 相似文献
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浆固碎石桩成桩注浆渗透影响分析 总被引:1,自引:0,他引:1
浆固碎石桩作为一种新型软土地基处理技术,其主要通过注浆改善桩体的加固效果,同时通过浆体渗透来改善桩周土体的物理力学性质,从而减小浆固碎石桩复合地基沉降。针对浆体对桩周土体的渗透作用,按照平面轴对称问题,推导出注浆渗透影响范围的计算方法和浆固区压缩模量计算公式,并通过室内模型试验研究,验证了浆固区压缩模量计算公式的正确性。随后,利用数值计算分析,对浆固区影响范围进行量化分析,并通过数值拟合得到了考虑注浆渗透影响的桩体等效半径计算公式。所得结果对工程设计具有重要的指导意义。 相似文献
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新型套管排水桩技术的原理是将排水盲沟与桩结合起来,排水盲沟提供了桩周的排水通道,在地震发生时,可以有效降低桩周土体产生的超孔隙水压力,达到抗液化的目的。开展了套管桩与不设置排水盲沟的普通桩的静动力数值模拟,结果表明:套管桩的复合地基承载力与等直径普通桩的承载力接近,排水盲沟的设置没有减弱桩的承载能力,在地震作用下,套管桩的排水盲沟可以有效降低桩周产生的超孔隙水压力,提高桩周土体的有效应力,达到地基抗液化的目的。 相似文献
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通过分别开展包裹碎石桩加固、碎石桩加固以及未加固的饱和砂土液化振动台试验,对比分析不同加固类型下的抗液化性能,重点剖析包裹碎石桩加固的砂土液化机理。试验表明:振动加载过程中,包裹碎石桩始终保持桩体的完整性与良好的排水性能且其加固模型地基的总沉降量相较于未加固模型地基减少了50%,相较于碎石桩加固模型地基减少了31.8%。包裹碎石桩加固模型排出水量较未加固模型地基提高了33.3%,较碎石桩加固模型地基提高了16.6%;包裹碎石桩加固模型地基的超静孔压值下降显著且地基下层砂土出现未液化的现象;并进一步发现包裹碎石桩的排水加固作用沿土层竖向深度呈递增趋势。因此,可以发现包裹碎石桩加固砂土液化的抗震性能优于碎石桩。 相似文献
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对由碎石桩和CFG桩构成的多桩型复合地基的作用机理进行分析,通过数值模拟,对多桩型复合地基的动力特性进行研究,探讨桩型配比、桩径、桩长、CFG桩桩体刚度和碎石桩桩体渗透性等设计参数对多桩型复合地基动力特性的影响。研究结果表明:相同条件下地震期多桩型复合地基的动变形小于碎石桩复合地基而大于CFG桩复合地基,震后沉降量相对较小,在工程设计时碎石桩与CFG桩的桩型配比宜为4∶5;随桩体长度、桩体直径和CFG桩刚度的增加,多桩型复合地基地震期的竖向动变形逐渐减小;随碎石桩桩体渗透性的增加,多桩型复合地基中的超动孔隙水压力减小,震后沉降量降低。 相似文献
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Study on wall-type gravel drains as liquefaction countermeasure for underground structures 总被引:1,自引:0,他引:1
R. P. Orense I. Morimoto Y. Yamamoto T. Yumiyama H. Yamamoto K. Sugawara 《Soil Dynamics and Earthquake Engineering》2003,23(1):114
One of the most dramatic causes of damage to engineering structures during earthquakes has been the development of soil liquefaction beneath and around the structures. In order to dissipate the excess pore water pressures near structures, gravel drains are usually employed. In this study, the use of recycled concrete crushed stones as gravel drain materials is addressed. In order to investigate the performance of wall-type gravel drains, two series of shaking table tests were performed. The test results showed that gravel drains, when appropriate grain size distribution is considered, effectively dissipate the excess pore water pressure underneath the structure, and consequently reduce the magnitude of uplift. To supplement the laboratory tests, finite element analyses were also performed. For specified structure, ground and earthquake conditions, there is a critical width of gravel drain at which no uplift of structure will occur. The results of the model tests and the finite element analyses were then employed in developing design charts for determining the critical width of gravel drain to prevent buoyant rise of structure when the surrounding soil mass liquefies. 相似文献
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Development of new drain method for protection of existing pile foundations from liquefaction effects 总被引:1,自引:0,他引:1
Naoyuki Harada Ikuo Towhata Tadashi Takatsu Shinsuke Tsunoda Vlatko Sesov 《Soil Dynamics and Earthquake Engineering》2006,26(2-4):297-312
Pile foundation as well as other underground structures could be seriously affected by soil liquefaction during strong earthquakes. Damages on pile foundation due to liquefaction can be reduced by implementation of some soil improvement method. Main objective of present study is developing of drain method that can improve the soil in order to mitigate the destructiveness of liquefaction on superstructure supported by pile foundation. Series of shaking table tests were conducted on 2×2 pile foundation and soil model was improved by drains. Configurations of drains around piles, intensity of shaking were one of the parameters that were changing during the tests in order to investigate the response of pile foundation in improved soil condition.Shaking table tests and performed On-site experiment showed the following effects of the new drain method. (1) When the intensity of earthquake motion is 200 gal or less, generation of excess pore water pressure is reduced and the pile bending moment is decreased, (2) when the intensity of earthquake motion is stronger (300 gal or more), drainage effect prevents disappearance of subgrade reaction, and (3) proposed new type of drain can control excess pore water pressure without clogging. 相似文献
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Wen-Jong Chang Ellen M. Rathje Kenneth H. Stokoe II Brady R. Cox 《Soil Dynamics and Earthquake Engineering》2004,24(9-10):723
A dynamic full scale testing program was performed to quantitatively assess the effectiveness of prefabricated vertical drains as a liquefaction countermeasure. The testing program involved a new in situ liquefaction testing technique, which uses a large hydraulic vibrator to generate waves propagating through an embedded instrumentation area to measure the coupled soil-pore water response. The effectiveness of prefabricated vertical drains is assessed experimentally by comparing the pore pressure generation, pore pressure dissipation, and settlement from two reconstituted soil specimens; one without a drain in place and the other with a single drain installed. Because the prefabricated drain was installed during the specimen preparation process, no accompanying densification during installation occurred. Therefore, the effect of drainage alone was evaluated. The testing results show that the drainage provided by prefabricated drains can significantly reduce pore pressure generation, accelerate post-shaking pore pressure dissipation, and limit associated settlement. The outcome also shows that the new developed in situ liquefaction testing technique can be an alternative to quantitatively evaluate the effects of various liquefaction remediation techniques. 相似文献
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利用GDS循环三轴仪进行一系列饱和砂砾土不排水动三轴液化试验,研究其在循环荷载作用下的液化特性,分析含砾量对饱和砂砾土动强度和动孔压的影响规律。研究表明:含砾量对砂砾土液化性能影响较大,随着含砾量的增加砂砾土抗液化强度呈单调增加趋势;随循环周次的增加孔隙水压力不断升高,增长速率与所施加的循环应力幅值有关,同一固结压力下,振次比相同时循环动应力幅值越大动孔压比越大;破坏振次对动孔压增长模式存在影响,破坏振次较小时砂砾土动孔压增长模式呈双曲线型发展,破坏振次较大时砂砾土的动孔压增长模式可用反正弦函数来表示,且含砾量越大循环荷载引起的孔隙水压力越高;含砾量对砂砾土液化特性的影响可从砂砾土的微细观结构特征得到阐释,并借助其粒间状态参量进行分析。 相似文献
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孕震过程中孔隙压及地下水位变化的数值模拟 总被引:2,自引:2,他引:2
地震孕育过程中孕震区内各点的应力应变都将发生变化,介质的物性参数也将改变,因此孔隙压和地下水位随之改变。本文在研究孕震过程中包括扩容和断层蠕变效应在内的应力应变场的基础上,根据应力场与孔隙压场的耦合方程,把孔隙压场随应力场的应力变化定量地计算出来。计算结果表明,孕震过程中孔隙压的变化与应力场变的化的强弱及南的渗透性能等因素相关。孕震过程后期,震源区表现为扩容区并且孔隙压强以负压为主,此结果显示着震 相似文献
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无基坑振冲加密施工是一种比较先进的土石坝建筑方法。以海南省三亚市西部的宁远河中下游河段的大隆水利枢纽工程土石坝为研究对象,对其进行准确分区,以饱和-非饱和渗流理论为基础,通过三维有限元数值方法,模拟库水下降作用下的土石坝渗流场,并对各级水位下的孔压、流速及流向进行分析,评价大坝的渗流安全。研究结果表明:采用无基坑振冲加密施工方法后,坝体内填砂砾振冲层形成上游排水通道,在坝前水位骤降工况下,防渗土料内有效流速方向和渗透压力的方向由近水平的指向坝面变为竖直向下指向填砂砾振冲层,而且有效流速明显变大,利于渗透水通过填砂砾振冲层排到下游,有利于上游坝体稳定。 相似文献
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The effect of stress on pore pressure in rocks and the mechanism of water table anomaly before earthquakes 总被引:1,自引:0,他引:1
Triaxial compressive experiments of porous rock samples were carried out under various confining pressures and initial pore
pressures without drainage; axial strain and pore pressure were observed versus differential stress. The results of such experiments
show that pore pressure increases with increase of differential stress at low differential stress; pore pressure decreases
with increase of differential stress at medium and high differential stress. Pore pressure also increases with large amplitude
decrease of differential stress at high differential stress. Based on such experiments, it is suggested that water table anomaly
before an earthquake reflects the change of differential stress in crustal rocks. The anomalous behavior of water tables in
the epicentral and peripheral areas before the great Tangshan earthquake of July 28, 1976 are explained by such suggestion.
The Chinese version of this paper appeared in the Chinese edition ofActa Seismologica Sinica,13, 88–95, 1991.
This study is supported by the Chinese Joint Seismological Science Foundation. Professor Yongtai Che gave us much help in
applying fund support and supplying earthquake case histories. 相似文献
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One method of mitigating the damaging effects of earthquake-induced liquefaction is to provide rapid dissipation of excess pore pressures by the use of vertical drains through the liquefiable material. Drain systems are currently designed using a chart-based approach. Field experience suggests that the performance of these installations cannot yet be accurately predicted.
In this paper, high quality centrifuge testing is used to help clarify drain behaviour. It will be established, supported by centrifuge test data, that the pore water from a radially expanding zone of soil contributing to drainage through the drains is developed. Naturally, the geometry of this expanding zone changes with time. It will be shown that fluid from deeper strata is drained first, reducing the effectiveness of the drain for near-surface soil layers. It is concluded that these zones are useful in analysing more complicated drain system geometries. 相似文献