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1.
Pile reinforcement mechanism of soil slopes 总被引:1,自引:1,他引:0
Stabilizing piles are widely used as an effective and economic reinforcement approach for slopes. Reasonable designs of pile reinforcement depend on the understanding of reinforcement mechanism of slopes. A series of centrifuge model tests were conducted on the pile-reinforced slopes and corresponding unreinforced slopes under self-weight and vertical loading conditions. The deformation of the slope was measured using image-based analysis and employed to investigate the pile reinforcement mechanism. The test results showed that the piles significantly reduced the deformation and changed the deformation distribution of the slope, and prevented the failure occurred in the unreinforced slope. The pile influence zone was determined according to the inflection points on the distribution curves of horizontal displacement, which comprehensively described the features of the pile–slope interaction and the characteristics of reinforced slopes. The concepts of anti-shear effect and compression effect were proposed to quantitatively describe the restriction features of the piles on the deformation of the slope, namely the reduction in the shear deformation and the increase in the compression deformation, respectively. The pile reinforcement effect mainly occurred in the pile influence zone and decreased with increasing distance from the piles. There was a dominated compression effect in the vicinities of the piles. The compression effect developed upwards in the slope with a transmission to the anti-shear effect. The anti-shear effect became significantly dominated near the slip surface and prevented the failure that occurred in the unreinforced slope. 相似文献
2.
Progressive failure behavior of pile-reinforced clay slopes under surface load conditions 总被引:2,自引:0,他引:2
Stabilizing piles are widely used to improve stability level of slopes to avoid landslides. In this paper, the full failure process of clay slopes reinforced using stabilizing piles was produced using serialized centrifuge model tests under surface loading conditions. The strength of pile material and the pile location closer to the slope top were both indicated to have a positive influence on the limit bearing capacity of the reinforced slope on the basis of test observations. The displacement field over the reinforced slope was measured during loading and used to capture a significant progressive failure caused by the surface loading. Local failure started near the inner edge of the load plate and expanded in a downward direction to produce a final slip surface. The pile exhibited a bending failure coupled with the progressive failure of the slope. The failure mechanism could be illustrated with the deformation localization in the slope that developed prior to the slip surface. The surface load exhibited a significant spreading behavior within the slope according to the displacement distribution of the slope. 相似文献
3.
以新建杭绍台铁路通过浙江嵊州及新昌硅藻土地区为研究背景,基于单桩静载、边坡降雨、复合地基承载性能、基床原位激振等现场试验,研究了不同桩型加固硅藻土地基的适宜性、降雨条件下硅藻土边坡变形特性和防护措施、硅藻土桩筏复合地基特性以及基床动力特性。结果表明:CFG桩、素混凝土桩及钢筋混凝土桩适用于硅藻土地基加固,而螺杆桩由于存在挤土效应、高压旋喷桩成桩效果较差不适用;干湿循环作用下硅藻土自然边坡易形成网状裂隙导致浅层稳定性不足,拱形骨架对硅藻土边坡有较好的防护效果,而锚杆框架梁由于钻孔施工易导致硅藻土软化,不适用于硅藻土边坡防护;CFG和素混凝土桩复合地基能够满足硅藻土路基变形控制要求,且素混凝土桩筏结构整体性更好;基床结构中设置毛细防排水板具有良好的防排水效果,保证了水份能够及时排出,避免对基床和硅藻土地基不利影响。 相似文献
4.
5.
饱和砂土地基上抗滑桩加固边坡的动力离心模型试验研究 总被引:5,自引:1,他引:4
动力离心模型试验是研究可液化地基上抗滑桩加固边坡地震动力响应的有效手段之一。使用铜质抗滑模型桩,采用黏度为50 cs的甲基硅油做为孔隙流体,通过抽真空法制作了饱和地基上的加固边坡模型。进行动力离心模型试验,研究了地震作用下饱和砂土地基中动孔压、边坡变形与土体加速度和抗滑桩弯矩的响应特征。试验结果表明,地震作用导致的动力附加弯矩相当于震前静力弯矩的87 %,说明地震作用与地基液化导致的附加弯矩不容忽视,该结论可为边坡进行抗震设计与稳定分析提供有意义的参考。 相似文献
6.
基于复合地基-上部结构相互作用的静力分析已取得一定的研究成果,但其在动力荷载作用下,特别是地震作用下的动力响应却相当匮乏。首先借助有关试验通过ABAQUS和EERA的模拟分析,验证了基于Drucker-Prager屈服准则的弹塑性模型能较好地反映土体非线性动力特性以及采用有限元与无限元耦合的方法对土体无限边界的模拟。在此基础上,针对实际问题建立了刚性桩复合地基-筏板-上部结构体系整体有限元模型,对其进行动力弹塑性时程分析,并讨论了该复合地基与桩基对地震响应的差异。深入研究了不同强度地震作用下,刚性桩复合地基的工作机制,包括桩体、褥垫层、筏板的动力响应以及上部结构的地震反应和抗震性能。结果表明,小震时褥垫层基本没有减震效果,大震时复合地基的抗震性能优于桩基。地震越强烈,减震效果越明显,但作用有限,减震系数一般在0.8以上,可为工程实践提供参考。 相似文献
7.
为了得到土质边坡中微型抗滑桩的破坏机制及边坡的破坏模式,通过3组大型物理模型试验对单排与三排微型抗滑桩加固黏性土边坡进行了研究。在加载过程中进行了位移和桩体应变的测量,最后进行开挖观察桩体破坏形态。试验结果表明,三排微型桩具有良好的抗滑效果,其承载力较单排桩提高了51.5%,且允许滑体产生较大位移,有效延缓坡体垮塌,适用于应急抢修工程。边坡会在加桩位置向前产生弧形次生滑面,并与预设滑面贯通;对于三排桩,第3排桩前出现桩土脱空区,坡面产生纵向劈裂缝。桩体变形呈S形,发生弯曲变形引起张拉与压剪破坏,而不是岩质边坡中滑面处的受剪断裂破坏。桩身所受最大弯矩分布于滑面以上,对于三排桩,第1排所受弯矩最大,第3排其次,第2排最小。其研究结果对了解微型桩的抗滑和破坏机制具有参考意义。 相似文献
8.
Integrated analysis of a coupled mechanism for the failure processes of pile-reinforced slopes 总被引:3,自引:1,他引:2
A series of centrifuge model tests was conducted to investigate the failure mechanism of pile-reinforced slopes under self-weight loading and vertical loading conditions. An integrated analysis method was proposed based on the image-based measurement results of the displacement of the slope in the tests. The failure process of a pile-reinforced slope was quantified based on the measured deformation process over the entire slope, which was shown to depend primarily on the loading conditions. The deformation localisation was discovered in the slope during loading and was effectively described using a newly introduced index, the Diversity Factor of Displacement (DFD). The deformation localisation of the slope developed and caused the progressive formation of the slip surface. At the same time, a local failure at a point on the slip surface resulted in new deformation localisation, and the influence expanded with the centre of the failure point and waned with increasing distance from the failure point. The deformation localisation process and the deformation-failure process of the piles interacted as both cause and effect and developed alternately. The failure mechanism of the pile-reinforced slopes was used to explain the effects of several influencing factors on the bearing capacity of the reinforced slope, such as the pile spacing, pile location, and gradient of the slope. 相似文献
9.
刚性桩复合地基抗震性能的振动台试验研究 总被引:3,自引:0,他引:3
为研究刚性桩复合地基的抗震性能,设计并完成了刚性桩复合地基1:10比尺的振动台试验。试验采用柔性容器这一较新的技术较好地模拟了地基在地震作用下的振动变形。此外,为解决模型与原型难以较好相似的问题,模型中尝试采用了在基础底板施加竖向力、在结构上附加阻尼器等措施。通过大量激振试验,对刚性桩复合地基的地震反应性态、柔性容器的效果等问题进行了研究。结果表明,柔性容器能够较好地解决模型试验的边界问题,刚性桩复合地基具有良好的抗震性能,桩身应变在地震作用下均未达到极限值,上部结构特性对桩身变形有一定影响,振动使土体对基础的约束减弱,但对桩的约束增强。 相似文献
10.
为研究坡顶加载条件下黏性土坡的承载特性和变形规律,进行了素土坡和土钉加固土坡的加载离心模型试验。测量了土坡的承载和变形过程。通过对比两种土坡的承载特性和变性规律,土钉的加固作用体现在:限制了土坡向坡面方向的位移,使土坡的承载能力得到了明显提高;在加固土坡内形成的土钉影响区域改善了加载底板边缘处的薄弱程度;增大了土坡中上部土体的竖向压缩变形,减小了剪切变形,增强了土坡的稳定性。土坡上部土钉的加固效果随着坡顶荷载的增大而越明显;土坡中下部土与土钉的相互作用越靠近坡面越强 相似文献
11.
Piles are frequently used to transfer the heavy compressive loads to strong soil layers located in the depth of bed. In addition, such piles may be subjected to combination of repeated compressive and tensile loads due to earthquake, wind, etc. This paper describes a series of laboratory model tests, at unit gravity, performed on belled pile, embedded in unreinforced and geocell-reinforced beds. The tests were performed to evaluate the beneficial effect of geocell in decreasing the downward and upward displacements and performance improvement of the uplift response of belled pile under repeated compressive and tensile loads. Pile displacements due to fifty load repetitions were recorded. The influence of the height of geocell above the bell of pile, an additional geocell layer at the base of belled pile, and the number of load cycles on pile displacements were investigated. The test results show that the geocell reinforcement reduces the magnitude of the final upward displacement. It also acts as a displacement retardant, and changes the behaviour of belled pile from unstable response condition due to excessive upward pile displacement in unreinforced bed to approximately steady response condition. Therefore, the geocell reinforcement permits higher tensile loads or increased cycling. The efficiency of reinforcement in reducing the maximum upward displacement of the pile (i.e. pull-out resistance) was increased by increasing the height of geocell above the bell of the pile. Furthermore, the comparison showed that a specific improvement in upward and downward displacement and the stability against uplift can be achieved using an additional geocell layer at the base. The geocell reinforcement may reduce the required length of pile shaft, consequently reducing required excavation, backfill, and pile’s material. Simple dimensional analysis showed the need for an increased stiffness of the geosynthetic components in order to match prototype-scale performance similitude. 相似文献
12.
Thuraisamy Thavaraj W. D. Liam Finn Guoxi Wu 《Geotechnical and Geological Engineering》2010,28(3):275-286
A quasi-3D continuum method is presented for the dynamic nonlinear effective stress analysis of pile foundation under earthquake
excitation. The method was validated using data from centrifuge tests on single piles and pile groups in liquefiable soils
conducted at the University of California at Davis. Some results from this validation studies are presented. The API approach
to pile response using p–y curves was evaluated using the quasi-3D method and the results from simulated earthquake tests on a model pile in a centrifuge.
The recommended API stiffnesses appear to be much too high for seismic response analysis under strong shaking, but give very
good estimates of elastic response. 相似文献
13.
U. S. Okyay D. Dias P. Billion D. Vandeputte A. Courtois 《Geotechnical and Geological Engineering》2012,30(4):1013-1024
The earthquake resistant design of structures depends upon the soil-structure interaction during seismic excitation. The dynamic behavior of surface foundations and deep foundations has been investigated by several authors (Gazetas in Soil Dyn Earthq Eng 2(1):2–42, 1983; Pecker in Dynamique des sols. Presses de l’Ecole Nationale des Ponts et Chaussées, Paris, 1984; Sieffert and Cevaer in Manuel des fonctions d’impédance. Ouest-Editions, Nantes, 1992, etc.) but the dynamic behavior of pile-reinforced soils has not been sufficiently studied yet. The design of pile-reinforced soils comprises the design of the rigid piles and the design of the earth-platform. The foundation system studied in this article consists of an earth-platform over a soft ground reinforced by deep piles. In order to understand the dynamic behavior of a rigid pile, a series of dynamic tests is conducted on an experimental site. The vertical and horizontal impedances of the slab foundation are obtained with and without rigid piles. The numerical models are developed to interpret these dynamic tests. The numerical and experimental impedance functions are compared in both the vertical and the horizontal directions. A sensitivity analysis on the influence of the physical and geometrical properties of rigid piles on the impedance functions is presented. 相似文献
14.
灌注桩后注浆工艺能提高桩的承载力、减小变形、增强桩的质量稳定性。根据某工程注浆和未注浆钻孔灌注桩的单桩静载试验的分析与对比,结合试验的荷载位移曲线、桩身轴力分布、桩顶荷载与桩端荷载、桩顶沉降与桩身弹性压缩量等关系,探讨钻孔灌注桩注浆前后桩土体系荷载传递的变化规律和某些影响因素,对了解桩端压力注浆桩的承载性状及类似工程的设计有一定意义。 相似文献
15.
A series of centrifuge shaking table model tests are conducted on 4?×?4 pile groups in liquefiable ground in this study, achieving horizontal–vertical bidirectional shaking in centrifuge tests on piles for the first time. The dynamic distribution of forces on piles within the pile groups is analysed, showing the internal piles to be subjected to greater bending moment compared with external piles, the mechanism of which is discussed. The roles of superstructure–pile inertial interaction and soil–pile kinematic interaction in the seismic response of the piles within the pile groups are investigated through cross-correlation analysis between pile bending moment, soil displacement, and structure acceleration time histories and by comparing the test results on pile groups with and without superstructures. Soil–pile kinematic interaction is shown to have a dominant effect on the seismic response of pile groups in liquefiable ground. Comparison of the pile response in two tests with and without vertical input ground motion shows that the vertical ground motion does not significantly influence the pile bending moment in liquefiable ground, as the dynamic vertical total stress increment is mainly carried by the excess pore water pressure. The influence of previous liquefaction history during a sequence of seismic events is also analysed, suggesting that liquefaction history could in certain cases lead to an increase in liquefaction susceptibility of sand and also an increase in dynamic forces on the piles. 相似文献
16.
Chunyang Liu Hoda Soltani Kanthasamy K. Muraleetharan Amy B. Cerato Gerald A. Miller Sri Sritharan 《Acta Geotechnica》2016,11(6):1431-1444
Presented in this paper are results of two centrifuge tests on single piles installed in unimproved and improved soft clay (a total of 14 piles), with the relative pile–soil stiffness values varying nearly two orders of magnitude, and subjected to cyclic lateral loading and seismic loading. This research was motivated by the need for better understanding of lateral load behavior of piles in soft clays that are improved using cement deep soil mixing (CDSM). Cyclic test results showed that improving the ground around a pile foundation using CDSM is an effective way to improve the lateral load behavior of that foundation. Depending on the extent of ground improvement, elastic lateral stiffness and ultimate resistance of a pile foundation in improved soil increased by 2–8 times and 4–5 times, respectively, from those of a pile in the unimproved soil. While maximum bending moments and shear forces within piles in unimproved soil occurred at larger depths, those in improved soil occurred at much shallower depths and within the improved zone. The seismic tests revealed that, in general, ground improvement around a pile is an effective method to reduce accelerations and dynamic lateral displacements during earthquakes, provided that the ground is improved at least to a size of 13D × 13D × 9D (length × width × depth), where D is the outside diameter of the pile, for the pile–soil systems tested in this study. The smallest ground improvement used in these tests (9D × 9D × 6D), however, proved ineffective in improving the seismic behavior of the piles. The ground improvement around a pile reduces the fundamental period of the pile–soil system, and therefore, the improved system may produce larger pile top accelerations and/or displacements than the unimproved system depending on the frequency content of the earthquake motion. 相似文献
17.
抗滑桩加固斜坡软弱地基路堤的数值模拟 总被引:2,自引:0,他引:2
在路堤荷载作用下,斜坡软弱地基易产生侧向变形过大、滑塌失稳等病害。路堤下坡脚处采用钢筋混凝土抗滑桩,以有效限制地基侧向变形,是斜坡软弱地基路堤的核心设计原则。采用三维快速拉格朗日有限差分法,经与室内土工离心模型试验成果对比、校核,建立抗滑桩加固斜坡软弱地基路堤的精细化数值分析模型,研究抗滑桩桩距、桩长、桩身弹性模量、桩身横截面尺寸及桩位等设计参数对其内力、变位的影响。研究表明:下坡脚处实施抗滑桩可显著约束斜坡软弱地基侧向变形;需综合考虑桩身受力、经济性、施工等因素确定合理的桩距;桩长应深入滑移面以下,但随着桩长的增长,加固效果增长不明显;随着桩身弹性模量、桩身横截面尺寸的增加,抗滑桩的加固效果得到一定提高;抗滑桩宜设置在下坡侧路堤边坡的中部。 相似文献
18.
强震中场地砂土液化产生的土层侧移对地面建筑结构和地下生命线工程造成了严重的破坏。可以预见,微倾斜液化场地的土层侧移也将对地铁地下结构的地震安全造成严重的威胁。鉴于此,开展了微倾斜(倾角为6o)可液化场地中两层三跨地铁地下车站结构与区间隧道连接部位地震反应的大型振动台模型试验研究。结果表明:微倾斜可液化场地中地铁车站结构两侧地基出现了明显的非对称液化分布特征,坡体下方水平土层比上方水平土层更易液化;因坡体内土体液化沿坡向下流滑引起了下方水平土层发生了明显的地面抬升,总体上坡体段内的地面侧移量最大,下方水平土层地面侧移量次之,坡体上方水平土层地面侧移量最小。同时,在试验过程中也发现,隧道和车站结构之间发生了明显的差异上浮,可能会造成连接部位附近结构的应力集中或加重该部位的地震破坏。 相似文献
19.
Uncoupled analysis of stabilizing piles in weathered slopes 总被引:15,自引:0,他引:15
This paper describes a simplified numerical approach for analyzing the slope/pile system subjected to lateral soil movements. The lateral one-row pile response above and below the critical surface is computed by using load transfer approach. The response of groups was analyzed by developing interaction factors obtained from a three-dimensional nonlinear finite element study. An uncoupled analysis was performed for stabilizing piles in slope in which the pile response and slope stability are considered separately. The non-linear characteristics of the soil–pile interaction in the stabilizing piles are modeled by hyperbolic load transfer curves. The Bishop's simplified method of slope stability analysis is extended to incorporate the soil-pile interaction and evaluate the safety factor of the reinforced slope. Numerical study is performed to illustrate the major influencing parameters on the pile-slope stability problem. Through comparative studies, it has been found that the factor of safety in slope is much more conservative for an uncoupled analysis than for a coupled analysis based on three-dimensional finite element analysis. 相似文献
20.
斜坡上的基桩具有承重和阻滑的双重功能,其受力变形性状远比平地上的情形复杂。采用模型试验和数值模拟相结合的方法研究了其水平承载特性及影响因素。模型试验结果表明:临坡距对基桩的水平承载变形性能有较大影响。同一级荷载下,临坡距较大的桩身水平位移小于临坡距较小的基桩;临坡距较大基桩的临界荷载和极限承载力也大于临坡距小的基桩。数值模拟研究结果表明:基桩水平极限承载力随着斜坡坡比的增大而减小,随着临坡距的增大而增大,与模型试验的结果基本一致。对比分析了斜坡和平地基桩水平承载变形性能的差别,得出了可考虑坡比和临坡距的斜坡基桩水平极限承载力简便计算方法,可为有关规范的修订以及工程设计提供参考。 相似文献