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1.
The influence of vertical loads on the lateral response of group piles installed in sandy soil and connected together by a concrete cap is studied through finite elements analyses. The analyses focus on the five piles in the middle row of 3 × 5 pile groups. The vertical load is applied by enforcing a vertical displacement equivalent to 2% of the pile diameter through the pile cap prior to the application of the lateral loads. The results have shown that the lateral resistance of the leading pile (pile 1) does not appear to vary considerably with the vertical load. However, the vertical load leads to 23%, 36%, 64%, and 82% increase in the lateral resistance of piles 2–5, respectively. The increase in the lateral pressures in the sand deposit is the major driving factor to contribute the change in the lateral resistance of piles, depending on the position of the pile in the group. The distribution of lateral loads among piles in the group tends to be more uniform when vertical loads were considered leading to a more economical pile foundation design. 相似文献
2.
Yoon Seok Choi Jintae Lee Monica Prezzi Rodrigo Salgado 《Geotechnical and Geological Engineering》2017,35(4):1587-1604
Although the loads applied on piles are usually a combination of both vertical and lateral loads, very limited experimental research has been done on the response of pile groups subjected to combined loads. Due to pile–soil–pile interaction in pile groups, the response of a pile group may differ substantially from that of a single pile. This difference depends on soil state and pile spacing. This paper presents results of experiments designed to investigate pile interaction effects on the response of pile groups subjected to both axial and lateral loads. The experiments were load tests performed on model pile groups (2 × 2 pile groups) in calibration chamber sand samples. The model piles were driven into the sand samples prepared with different relative densities using a sand pluviator. The combined load tests were performed on the model pile groups subjected to different axial load levels, i.e., 0 (pure lateral loading), 25, 50, and 75% of the ultimate axial load capacity of the pile groups, defined as the load corresponding to a settlement of 10% of the model pile diameter. The combined load test results showed that the bending moment and lateral deflection at the head of the piles increased substantially for tests performed in the presence of axial loads, suggesting that the presence of axial loads on groups of piles driven in sand is detrimental to their lateral capacity. 相似文献
3.
为提高桩身变形较大时纵横荷载单桩的设计计算水平,假定地基反力系数沿深度线性增加,考虑土体屈服及纵向荷载的P-?效应并计入桩身自重和桩侧摩阻力的影响,得到了地面以下桩身变形和内力的幂级数解。结合已有的地面以上桩身响应的幂级数解,采用Fortran语言编制了计算程序。计算结果表明:桩顶位移、地面处桩身位移及桩身最大弯矩均随纵横向荷载和自由段桩长的增加而增大,并随土体屈服位移的增加而减小;纵向荷载足够大时桩基失稳;桩顶约束条件对桩的响应影响很大。计算值与模型试验的实测值吻合较好,所得解和程序是可靠的。 相似文献
4.
A Winkler model approach for vertically and laterally loaded piles in nonhomogeneous soil 总被引:1,自引:0,他引:1
Hiroyoshi Hirai 《国际地质力学数值与分析法杂志》2012,36(17):1869-1897
An investigation is made to present analytical solutions provided by a Winkler model approach for the analysis of single piles and pile groups subjected to vertical and lateral loads in nonhomogeneous soils. The load transfer parameter of a single pile in nonhomogeneous soils is derived from the displacement influence factor obtained from Mindlin's solution for an elastic continuum analysis, without using the conventional form of the load transfer parameter adopting the maximum radius of the influence of the pile proposed by Randolph and Wroth. The modulus of the subgrade reaction along the pile in nonhomogeneous soils is expressed by using the displacement influence factor related to Mindlin's equation for an elastic continuum analysis to combine the elastic continuum approach with the subgrade reaction approach. The relationship between settlement and vertical load for a single pile in nonhomogeneous soils is obtained by using the recurrence equation for each layer. Using the modulus of the subgrade reaction represented by the displacement influence factor related to Mindlin's solution for the lateral load, the relationship between horizontal displacement, rotation, moment, and shear force for a single pile subjected to lateral loads in nonhomogeneous soils is available in the form of the recurrence equation. The comparison of the results calculated by the present method for single piles and pile groups in nonhomogeneous soils has shown good agreement with those obtained from the more rigorous finite element and boundary element methods. It is found that the present procedure gives a good prediction on the behavior of piles in nonhomogeneous soils. Copyright © 2011 John Wiley & Sons, Ltd. 相似文献
5.
Satyendra Mittal B. Ganjoo Sunny Shekhar 《Geotechnical and Geological Engineering》2010,28(5):717-725
The screw anchor piles are installed in ground by screwing which is done with the help of torque motors. In this paper, the
lateral load capacity of screw anchor piles is examined through an experimental investigation carried on model piles embedded
in dry sand. The tests were carried on screw anchor piles with different number of helices provided in continuation. Lateral
loads were applied at different height above the soil surface. The embedment length of screw anchor piles was also varied
to study the behaviour of screw anchor piles under lateral loads. Some tests were conducted on plain shaft pile to compare
the lateral load capacity of screw anchor piles with that of plain shaft piles. An empirical equation for computation of lateral
loads has been developed considering lateral resistance, bearing resistance, uplift resistance and lateral resistance offered
by soil in pile on the basis of experimental results. A theoretical model for predicting lateral load capacity of screw anchor
piles in dry sand, consistent with the experimental findings has been developed in this study. 相似文献
6.
建立了三维数值模型,进行堆载-弹塑性地基-桩基共同作用有限元数值分析。在地面超载条件下,对自由场土体的侧向位移模式进行了探讨,得出了土体侧向变形规律。在此基础上,对堆载作用下邻近桩基的力学性状进行了分析,包括不同堆载大小、不同堆载距离和不同桩间距等情况下桩基的侧向变形和弯矩的变化规律。分析结果表明:随着堆载的增加,桩基的变形和弯矩都有显著的增长,桩基逐渐弯曲。在同样条件下,增加桩的刚度,桩身弯矩迅速减小,桩身刚度很大时,会发生整体侧移。桩间距和堆载距离对桩身弯矩和变形有重要影响,随着桩间距和堆载距离的增大,桩身的变形和弯矩都将减小。 相似文献
7.
大厚度黄土地基中大直径长桩、超长桩的应用急剧增多,但黄土地基中超长桩的承载变形机理、侧阻和端阻的发挥性状与普通桩差别较大。采用研制的黄土相似材料填筑模型,分别进行超长单桩和群桩竖向抗压静载试验,分析桩顶荷载作用下荷载-沉降、桩身轴力、桩侧阻力、桩端土体塑性区发展变化规律。研究结果表明:超长单桩在竖向荷载作用下,荷载主要由桩侧阻力承担,桩侧阻力由上向下逐步发挥,属纯摩擦桩,单桩破坏形式为刺入破坏,桩端土体塑性变形影响范围约为1.1 d。与单桩相比,超长群桩基础桩端承载力有较大幅度的提高,桩身轴力衰减深度范围有所减小,侧阻力沿桩身逐渐增大,桩端土层的影响范围约为1.25 d,与超长单桩的影响范围较为接近。本文的研究方法和结果可为大厚度黄土地区超长桩基的承载特性研究提供参考。 相似文献
8.
成层土中倾斜荷载作用下桩承载力有限元分析 总被引:7,自引:1,他引:6
利用有限元方法对现场单桩水平载荷试验进行模拟,在此基础上,分析了成层土中桩在倾斜荷载作用下其竖向分量的有利作用和横向土抗力分布特点。计算结果表明,在地面下一定范围内,倾斜荷载作用下的桩侧摩阻力比水平荷载作用下的桩侧摩阻力大。在土层分界处土抗力分布有明显的跳跃。达到一定深度后,横向土抗力主要是静止土压力,而由荷载引起的横向土抗力很小。承台能有效减小土体及桩的水平位移。模拟的灌注桩和钢管桩桩顶在地面以上的自由长度较小,竖向分量由于桩身挠曲变形而产生的P-Δ效应较小,所以就算例中的灌注桩和钢管桩而言,荷载倾斜度不大时,荷载竖向分量提高了桩的侧阻并由此增大桩侧土竖向应力,对桩水平承载力总体上起到了有利的作用。 相似文献
9.
A simplified method of numerical analysis has been developed to estimate the deformation and load distribution of piled raft foundations subjected to vertical, lateral, and moment loads, using a hybrid model in which the flexible raft is modelled as thin plates and the piles as elastic beams and the soil is treated as springs. Both the vertical and lateral resistances of the piles as well as the raft base are incorporated into the model. Pile–soil–pile, pile–soil–raft and raft–soil–raft interactions are taken into account based on Mindlin's solutions for both vertical and lateral forces. The validity of the proposed method is verified through comparisons with several existing methods for single piles, pile groups and piled rafts. Workable design charts are given for the estimation of the lateral displacement and the load distribution of piled rafts from the stiffnesses of the raft alone and the pile group alone. Additionally, parametric studies were carried out concerning batter pile foundations. It was found that the use of batter piles can efficiently improve the deformation characteristics of pile foundations subjected to lateral loads. Copyright © 2002 John Wiley & Sons, Ltd. 相似文献
10.
在大桩径、小桩距的群桩条件下,不仅有来自桩侧、桩端和承台传递的多重应力叠加,还有群桩对桩间土的夹持作用影响,桩-土-承台之间作用更加复杂。用有限差分软件模拟固定桩距、桩径,变化竖向荷载下桩-土-承台的相互作用。从各层土的侧摩阻力、不同位置桩的桩顶荷载、荷载-沉降关系、桩间土体位移等方面的计算结果分析桩-土-承台之间的相互影响。结果表明,荷载超出117.8 MN(略大于Pu/2,Pu为群桩极限承载力)后,群桩对上部桩间土的夹持作用开始减小,桩侧上部侧摩阻力增大;桩侧下部侧摩阻力在多重应力叠加作用下呈减小趋势,不同位置的桩侧摩阻力影响范围有差异;用群桩沉降达到5%倍桩径时的荷载作为群桩的竖向极限承载力是可取的;当沉降与桩径的比值超出1%后,承台分担荷载的比例逐渐增大,群桩分担荷载的比例减小。 相似文献
11.
Many structures (including transmission-line towers, bridges, tall buildings and coastal structures) are founded on piles, which are designed to transmit both vertical and horizontal forces, and resulting moments, to the load bearing strata. The design of such foundations for large lateral repeating loads (e.g. caused by wind, wave action, earthquake) and lateral earth pressures is a challenging task. This paper presents an experimental study that investigates the use of concentric rings (CRs) of small diameter (displacement) piles (SDPs) surrounding a monopile installed in dry sand, with the intention of limiting its rotation (lateral displacement) under repeated lateral loading. The test results showed that the rotation of the monopile, investigated for a range of different repeated lateral loading schemes, was reduced by 35?75% on account of the densification of the sand achieved during installation of the SDPs and also the lateral confinement they provided to the sand located within the CRs. Significant increases to both the cyclic stiffness and load carrying resistance of the monopile under lateral loading are documented with the inclusion of the SDPs. Further experimental as well as numerical studies are necessary to validate this novel technique and to optimise the geometrical size and network pattern of the SDPs and the CRs. 相似文献
12.
针对松花江砂卵石地层上的钢板桩围堰进行现场模型的水平载荷试验,介绍了模型的施工及试验方法,研究了双排钢板桩通过拉杆连接这种结构在水平载荷作用下的变形特性,同时进行了单排钢板桩水平载荷试验作为对比分析;通过测量其深层水平位移及桩顶位移,分析其桩顶位移预警值为及水平荷载的影响深度;通过测量拉杆轴力,分析水平力的传递,对类似工程设计有一定的参考作用。 相似文献
13.
在唐山LNG罐区对9根大直径钢筋混凝土灌注桩进行了竖向荷载现场试验,其中桩端后注浆工艺试桩3根,三岔双向挤扩工艺试桩3根,挤扩支盘工艺试桩3根。基于现场静荷载和桩身应力测试结果,分析了3种不同施工工艺钻孔灌注桩竖向荷载传递规律。试验结果表明:3种不同施工工艺的大直径深长钻孔灌注桩试桩荷载-沉降曲线没有明显拐点,后注浆工艺试桩荷载传递过程表现为摩擦桩的特性,桩侧阻力几乎承担全部荷载,而三岔双向挤扩支盘工艺和挤扩支盘工艺试桩荷载传递过程表现为端承摩擦桩的特性,桩端阻力占总荷载的20%~30%;3种不同施工工艺试桩的轴力及桩-土相对位移变化规律基本相似,桩侧桩端阻力非同步发挥且相互影响,桩侧摩阻力均表现出强化现象。对整个罐区要求单桩承载力特征值不小于8 100 kN。3种施工工艺的钻孔灌注桩承载力均能满足要求。 相似文献
14.
通过海洋环境条件下大直径管桩的垂直和水平荷载试验,分析了管桩在垂直和水平荷载作用下的受力特点,得到了管桩的垂直极限承载力、侧摩阻力及端承力、轴向反力系数等结果,以及水平荷载作用下桩顶位移和转角关系、弯矩分布、土抗力、水平地基反力系数的比例系数和最大弯矩点等参数。试验结果表明:垂直荷载作用下,极限承载力可达12000kN,在沉桩过程中部分桩有一定程度的闭塞;大直径管桩能够抵抗水平荷载的作用,弹性长桩的受力性质主要受上部土层的影响。根据试验结果计算的水平地基抗力比例系数m值,对本工程及同类地质条件的桩基设计具有参考价值。 相似文献
15.
钙质砂地基单桩承载特性模型试验研究 总被引:3,自引:0,他引:3
根据实际工程中单桩受力特点,对足尺桩基进行等比例缩尺,考虑不同埋深、砂土颗粒级配等影响因素,开展室内小尺寸模型单桩的竖向拉拔、水平推移和竖向压载试验,分析桩身变位、变形、轴力等参数与桩基埋深、桩周砂土特性等因素的相互关系,探究钙质砂地基中单桩在不同受力方向下的承载性状,进而剖析钙质砂中桩-土相互作用机制。研究表明,钙质砂地基中,单桩变位、变形特点随着受力方向、埋深、桩周砂土特性等的变化存在明显差异;增大桩的埋深对竖向抗拔桩的意义大过竖向抗压桩;相同条件下桩在承受竖向抗压荷载时,增大埋深的作用主要体现在加载初期,随着荷载的逐渐增大,最终差别将逐渐减小;竖向抗压桩承载过程由以侧摩阻力承载为主发展为以桩端阻力承载为主;颗粒破碎和重分布会引起抗拔桩εmax在加载后期出现衰减;宽级配钙质砂中桩的抗拔能力较强,而单一粒组的钙质砂则在维持桩身稳定方面占优势;桩侧剪碎时的桩侧阻力衰减是随着颗粒破碎逐渐发生的,而桩端压碎时的桩侧阻力衰减主要发生在砂土被压碎瞬间。研究结果对钙质砂地基中的不同功能桩基的优化、设计和施工具有重要指导价值。 相似文献
16.
根据软土地基、非软土地基中长钻孔灌注桩静载荷试验和桩身轴力的测试结果,分析探讨了竖向荷载下长桩的受力性能及沉降特征的一些规律。桩侧土模量较高的非软土地区的长桩静力试桩所测得的结果表明,荷载传递和桩身压缩与软土地区超长桩性状相似,长桩的桩身压缩量相当可观,计算中应予以考虑。极限侧阻力与端阻力不同步发挥,不同深度处的不同土层处基桩的侧阻也不能同步发挥;同时指出相关规范中极限承载力计算公式的不严密之处,并且探讨说明了竖向荷载下的长群桩基础变形性状及沉降计算有待进一步的研究。本项研究对今后超长桩的理论研究和工程设计应用具有一定的借鉴作用。 相似文献
17.
为解释横向载荷作用下刚性桩的失稳机理,针对桩头自由的刚性桩做了一系列横向加载试验。基础土为粉质粘土,含水量介于9.85 %~13.85 %之间。由载荷-位移全过程曲线发现,刚性桩在横向载荷达到一定值时会失稳;由试验录像及土体剖面发现,由于土体的软化破坏,在桩后土体内会出现贯穿的局部破坏并形成一楔体,同时在土面伴随一不完全的椭圆形鼓包及一条平行于加载方向的拉伸裂缝,而在桩前土中,由于桩的挤压会形成一条侵彻沟。分析认为,对大位移刚性桩桩后土体的破坏是桩失稳的根本原因。 相似文献
18.
横向载荷作用下刚性桩变位规律研究 总被引:1,自引:0,他引:1
目前对横向受载刚性桩的研究主要集中在其承载力方面,对变化规律研究很少。为此提出了利用刚性桩上两点位移求桩上任意一点位移、桩回转中心位置及转角的方法。通过对粉质黏土中的刚性桩进行模型试验与数值计算发现,回转中心位置随位移和载荷的增大,先是急剧下降,然后变缓,最后基本趋于稳定,而且桩埋置参数与土力学参数对回转中心位置的变化规律影响很小;而桩的转角随位移增大近似线性变化。比较发现,由试验和数值计算得到的回转中心极限位置与由极限地基反力法得到的结果相差不大 相似文献
19.
The paper has proposed a design method considering interaction effects for a piled raft foundation. In this method, the raft is considered as a plate supported by a group of piles and soil. The ultimate load capacity of the pile group is taken into account in calculating the settlement when the foundation is subjected to a large vertical external load. In addition, this method supports estimation of the nonlinear behaviour of the piled raft foundation by considering the nonlinear behaviour of the piles.A step-by-step procedure to apply the proposed method to calculate the settlement and distribution of the bending moment of the piled raft foundation is introduced. To verify the reliability of the proposed method, models of a 16-pile raft and a 9-pile raft with different pile lengths embedded in homogeneous silica sand were tested in a centrifuge and comparisons were made between the results of the proposed method, the results of centrifuge tests, and those of Plaxis 3D. Good agreement between centrifuge modelling and the proposed method is demonstrated, thus showing the potential of the proposed method. 相似文献
20.
Pile group interaction effects on the lateral pile resistance are investigated for the case of a laterally loaded row of piles in clay. Both uniform undrained shear strength and linearly increasing with depth shear strength profiles are considered. Three-dimensional finite element analyses are presented, which are used to identify the predominant failure modes and to calculate the reduction in lateral resistance due to group effects. A limited number of two-dimensional analyses are also presented in order to examine the behaviour of very closely spaced piles. It is shown that, contrary to current practice, group effects vary with depth; they are insignificant close to the ground surface, increase to a maximum value at intermediate depths and finally reduce to a constant value at great depth. The effect of pile spacing and pile–soil adhesion are investigated and equations are developed for the calculation of a depth dependent reduction factor, which when multiplied by the limiting lateral pressure along a single pile, provides the corresponding variation of soil pressure along a pile in a pile row. This reduction factor is used to perform p–y analyses, which show that, due to this variation of group effects on the lateral soil pressures with depth, the overall group interaction effects depend on the pile length. Comparisons are also made with approaches used in practice that assume constant with depth reduction factors. 相似文献