共查询到19条相似文献,搜索用时 187 毫秒
1.
海洋环境中的导管架平台承受着风浪、地震等水平荷载,而平台的稳定对桩基础有严格要求,故研究水平荷载下导管架平台桩-土系统变形规律和相互作用机制具有重要意义。研制了1套导管架平台桩-土相互作用试验系统,主要由导管架平台试验模型子系统、电动伺服加载子系统、传感器与数据采集子系统、振动测试子系统组成,可用于研究冲击荷载、静载、循环荷载下导管架平台的桩身变形规律、桩基周围土体响应及平台的振动特性。通过初步试验结果表明,该系统能够如实反映水平荷载下桩-土间的相互作用和导管架平台的振动特性,验证了该系统的有效性。 相似文献
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导管架平台桩身循环往复运动将使桩周土体超孔隙水压增加、横向土抗力降低,从而导致桩基弱化。泥面以下6倍桩径处嵌固桩身的等效桩简化理论没有考虑桩基弱化对平台基础自然频率的影响,计算结果与实测值有一定差距。为研究桩基弱化对平台结构横向振动特性的影响,进行了比例尺为1:10的导管架平台模型试验,测量不同循环荷载作用之后导管架平台模型水平方向的振动特性。由试验结果可知,桩基横向土抗力在不同循环荷载作用过程中出现不同程度的衰减,桩基土抗力的衰减与桩身往复运动的幅值和次数有关。考虑桩-土相互作用时导管架平台模型两个水平方向的基础自然频率(基频)比等效桩理论计算值分别低15.5%和6.0%。桩基弱化后,实测值与计算值的差距增大到22.0%和13.4%。假设导管架-桩-土系统阻尼为比例阻尼,通过试验结果发现,桩基弱化对系统阻尼影响较小。 相似文献
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桩-土相互作用问题是岩土工程桩基础问题的关键点与难点,目前针对桩身在循环温度荷载与上覆结构荷载双重作用下的能源桩承载特性研究较少。在传统理想弹塑性模型及双曲线模型的基础上,采用分段非线性的方法对桩-土荷载传递骨干曲线进行了修正,并基于Masing’s循环准则,提出了适用于能源桩的桩-土荷载传递模型。利用改进的桩-土荷载传递模型对能源桩承载特性进行数值分析,着重研究了桩-土荷载传递参数比R对能源桩受力情况的影响。此外,为了探究在上覆结构荷载及循环温度荷载双重作用下,能源桩与周围土体之间的真实荷载传递关系及其结构热力学特性,开展了针对能源桩与周围土体之间相互作用问题的室内模型试验,监测了其桩身轴向应力及侧摩阻力随温度及深度变化的趋势,并与基于改进荷载传递模型的数值计算结果进行了对比。室内模型试验监测及数值计算结果显示:能源桩在上覆结构荷载及温度循环荷载双重作用下,其受力行为受改进的桩-土荷载传递循环曲线控制;基于改进的桩-土荷载传递循环曲线而建立的数值模型计算结果与试验结果基本吻合,改进的桩-土荷载传递模型能够较好发地反映能源桩实际的承载特性。 相似文献
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5.
斜坡上的桩基础的承载性能是复杂多变的。对于四川西部山地地形较广泛,且地基覆盖层多为特有的碎石土地层来说,水平受荷桩的相关研究还较少。为了研究碎石土地基斜坡上单桩基础的水平承载特性及桩土间的相互作用,通过现场水平静载荷试验在坡度为0°、15°、30°、45°的条件下,探讨桩身变形、桩身弯矩、土压力的变化。运用FLAC3D有限元分析软件得出水平荷载作用下,碎石土斜坡不同坡度的桩基础与桩周土之间的应力云图、位移云图的变化特点。将数值模拟结果与现场试验结果进行了对比,提出了单桩水平临界荷载和极限荷载在不同坡度区间内取值时的折减系数,为实际工程提供一定的参考。 相似文献
6.
一种确定导管架平台群桩p-y数据的方法 总被引:1,自引:0,他引:1
导管架海洋平台群桩基础的桩头约束是一种弹性约束。针对具有弹性约束桩头的群桩,提出了一种利用非线性地基梁群桩模型,通过迭代计算确定导管架平台群桩p-y数据的方法。该方法首先依据单桩p-y曲线,利用具有弹性约束桩头的群桩模型,计算桩头在总荷载作用下的水平位移;再利用Poulos相互作用系数确定由于群桩相互作用引起的桩头附加水平位移,将总荷载作用下的桩头水平位移与桩头附加水平位移叠加后的结果作为迭代计算的初始桩头水平位移。然后,依据桩头荷载与初始桩头水平位移,通过对单桩p-y数据的标定,确定其修正系数Ym,进而得到与第1次计算对应的群桩p-y数据。在接下来的迭代计算中,利用每次更新后的Ym确定该次计算使用的群桩p-y数据,并据此由群桩计算模型计算桩头位移,通过对单桩p-y数据标定确定相应的Ym,直到第i次与第i-1次计算出的Ym(i)和Ym(i-1)之间相对误差小于允许误差为止。由于该方法考虑群桩效应的p-y数据,且借助具有弹性约束桩头的群桩模型进行分析,从而使计算结果能客观反映具有弹性约束桩头群桩之间的相互作用与变形特性。 相似文献
7.
《地质科技情报》2021,40(1)
对于承受轴向荷载的水平受荷桩,以往研究大多基于线弹性或弹塑性水平荷载传递模型。为提升轴横受荷桩的计算设计水平,采用轴向荷载传递法计算桩身轴力,考虑桩身轴力引起的P-Δ效应,基于双曲线型水平荷载传递模型考虑桩-土体系变形的非线性特征,对成层土中轴横受荷桩的水平响应进行分析求解,得到了轴横荷载作用下桩身变形和内力的非线性有限差分解,并采用MATLAB语言编制了计算程序。使用模型试验算例与基于现场试验的有限元算例对非线性解的准确性进行对比验证,结果表明:计算结果与算例数据吻合良好,可靠性较高;采用不同荷载传递模型的计算结果在不同荷载水平下有所差异,在较大荷载水平下桩-土变形的非线性特点不容忽视。 相似文献
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自升式钻井船是广泛用于浅、中水域油气资源开发的重要设施,经常紧邻固定式导管架平台进行作业。钻井船插桩就位过程中大量土体被排开,挤土效应会导致邻近导管架平台桩基承受很大的附加荷载,影响平台的正常设计性能,该效应在黏土中尤为显著。针对黏土中钻井船插桩对邻近桩基的影响这一实际问题,现有规范和分析方法存在明显不足。为此,建立了一套数值分析方法,把这一复杂问题分解成相对独立、简单的两个方面进行分析:一是采用任意拉格朗日-欧拉(ALE)数值方法,计算自由场地插桩周围土体产生的位移场;二是利用桩基水平力与位移关系曲线,即P-Y曲线,采用杆系-土弹簧的传统方法计算土体位移产生的桩体加载。通过与已有离心试验数据的比较,验证了该方法的可靠性和适用性。研究揭示了自由场地土体的变形模式和流动机制,阐明了由于插桩邻近桩基产生的附加荷载变化规律,特别是发现了黏土变形参数 对插桩引起的自由场地土体位移场有显著影响,但对插桩引起的桩基加载影响较小。最后,针对导管架对桩基的桩头约束条件和插桩及导管架自身对桩基的线性叠加加载适用性问题给出了详细说明。 相似文献
9.
水平多向荷载下桩-土相互作用初探 总被引:1,自引:0,他引:1
利用香港科技大学离心机双向振动台,进行了群桩基础模型的水平单向和双向振动试验;振动过程中的桩身弯矩响应表明,群桩基础在单向振动中表现出的对称性在双向振动下不复存在;并进行了桩-土相互作用的颗粒流数值模拟,初步探寻了试验观测到的“垂向加载效应”的产生机制;同时通过简单的推导,指出了当前桩-土相互作用分析方法的局限性。在试验、数值和理论分析方面对水平多向荷载下的桩-土相互作用进行了初步研究,为今后的进一步研究提供了重要参考。 相似文献
10.
用有限单元法分析超长单桩的荷载传递 总被引:19,自引:6,他引:13
用描述桩侧摩阻力与桩-土相对位移关系的指数函数,推导出桩-土接触面本构模型,并设置了Goodman接触面单元来分析桩土相互作用。针对超长桩钢筋混凝土受应力大的特点,用混凝土的弹性非线性模型来分析受轴向荷载下钢筋混凝土的应力应变关系。编制的有限元程序能解决层状土及层状土导致沿桩身不同位置处桩-土相互作用不同特性,并针对工程实例桩变截面的特点,采用合理的计算手段使得按等截面桩计算分析结果与按实际变截面桩计算分析结果相同。用此程序对一工程实例进行了计算分析,计算结果与静载试验实测值较符合。 相似文献
11.
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
12.
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
13.
《Geomechanics and Geoengineering》2013,8(4):263-282
Vertical loads effect on the lateral response of a 3×5 pile group embedded in sand is studied through a two-dimensional finite element analysis. The soil-pile interaction in three-dimensional type is idealized in the two-dimensional analysis using soil-pile interaction springs with a hysteretic nonlinear load displacement relationship. Vertical loads inducing a vertical pile head displacement of 0.1-pile diameter increase the lateral resistance of the single pile at a 60 mm lateral deflection by 8%. Vertical loads inducing the same vertical displacement applied to a pile group spaced at 3.92-pile diameter increase the overall lateral resistance by 9%. The effect on individual piles, however, depends on the pile position. The vertical load decreases the lateral resistance of the leading pile (pile 1) by 10% and increases the lateral resistances of piles 2, 3, 4, and 5 by 9%, 14%, 17%, and 35%, respectively. Vertical loads applied to the pile group increase the confining pressures in the sand deposit confined by the piles but the rate of increase in those outside the group is relatively small, resulting in the difference in a balance of lateral soil pressures acting at the back of and in front of the individual pile. 相似文献
14.
The analysis of laterally loaded piles in soft clay is carried out idealising the pile as beam elements and the soil by nonlinear inelastic spring elements modeled with elasto-plastic sub-elements. The nonlinear hyperbolic model for static load condition is developed based on the undrained shear strength and modulus of subgrade reaction. An iterative procedure is adopted to perform a nonlinear finite element analysis and the effect of static lateral load on deflection is studied. Based on the lateral deflection at the end of first cycle (static load), the degradation factor is assumed and the p-y curve is modified. The cyclic load analysis is carried out using the static analysis program idealising the soil by modified p-y curve, which considers the effect of number of cycles and magnitude of cyclic lateral load. The results of the proposed analytical model compare well with the published experimental results, on piles subjected to one-way cyclic loading for different magnitude of cyclic lateral load and number of cycles. 相似文献
15.
Analysis of rectangular piles subjected to lateral loads in nonhomogeneous soil using a Winkler model approach 
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下载免费PDF全文 Hiroyoshi Hirai 《国际地质力学数值与分析法杂志》2015,39(9):937-968
An analytical approach using a Winkler model based on two lateral soil displacement components in a three‐dimensional soil is investigated to provide analytical solutions of horizontal response of a rectangular pile subjected to lateral loads in nonhomogeneous soil. The two lateral displacement components of a soil surrounding the rectangular pile are represented by the Fourier series of displacement potential functions in the elastic three‐dimensional analysis. The lateral stiffness coefficient of the rectangular pile shaft in nonhomogeneous soil is derived from the rocking stiffness coefficient taking into account rocking rotation of a rigid pile shaft. The relationship between horizontal displacement, rotation, moment, and shear force for the rectangular pile subjected to horizontal loads in nonhomogeneous soil is obtainable in the form of the recurrence equation. The formulation of lateral displacement and rotation for a rectangular pile subjected to lateral loads on the pile base in nonhomogeneous soil is proposed by taking into account Mindlin's equation and the equivalent thickness for soil layers in the equivalent elastic method. The difference of lateral behavior between square and circular piles subjected to lateral loads is insignificant. The effect of aspect ratio of the rectangular pile on the lateral behavior is great for the lower stiffness ratio between pile and soil and the larger length–equivalent diameter ratio. The effect of the value of Poisson's ratio of soil on lateral stiffness coefficient is relatively small except Poisson's ratio close to 0.5. The comparison of the results calculated by the current method for a rectangular pile subjected to lateral loads in nonhomogeneous soil has shown good agreement with those obtained from the analytical methods and the finite element method. Copyright © 2015 John Wiley & Sons, Ltd. 相似文献
16.
对桩及承台采用线弹性有限元模型,对承台下桩周土采用弹塑性有限元模型,对群桩以外的土体采用线弹性无限元模型,在桩土接触面上设置接触面单元,利用三维弹塑性有限元对桩%D土%D承台相互作用进行了分析。得出了如下结论 :承台下桩顶反力总体表现出角桩最大,边桩次之,中桩最小的分布规律,随着作用在承台上的荷载增大,桩顶反力趋于均匀分布,承台下桩侧摩阻力是由桩端向桩顶逐渐发展的,承台对桩上部侧摩擦阻力存在削弱作用。为了验证本文方法的可行性,对承台下有九桩的情况进行了静载试验,将试验结果与本文计算结果进行了比较。 相似文献
17.
This article presents a method for the nonlinear analysis of laterally loaded rigid piles in cohesive soil. The method considers the force and the moment equilibrium to derive the system equations for a rigid pile under a lateral eccentric load. The system equations are then solved using an iteration scheme to obtain the response of the pile. The method considers the nonlinear variation of the ultimate lateral soil resistance with depth and uses a new closed‐form expression proposed in this article to determine the lateral bearing factor. The method also considers the horizontal shear resistance at the pile base, and a bilinear relationship between the shear resistance and the displacement is used. For simplicity, the modulus of horizontal subgrade reaction is assumed to be constant with depth, which is applicable to piles in overconsolidated clay. The nonlinearity of the modulus of horizontal subgrade reaction with pile displacement at ground surface is also considered. The validity of the developed method is demonstrated by comparing its results with those of 3D finite element analysis. The applications of the developed method to analyze five field test piles also show good agreement between the predictions and the experimental results. The developed method offers an alternative approach for simple and effective analysis of laterally loaded rigid piles in cohesive soil. Copyright © 2011 John Wiley & Sons, Ltd. 相似文献
18.
This paper presents a three‐dimensional finite element analysis of the response of battered piles to the combined lateral and vertical pullout loads. Analyses are carried out using an elastoplastic constitutive law based on the non‐associated Mohr–Coulomb criterion. The influence of the contact condition at the pile–soil interface is also investigated. Analyses show that the load's inclination with regard to the pile's axis affects both the lateral and axial response of the battered piles. Analyses also show that the pullout capacity of battered piles is affected by the pile's inclination regarding the vertical axis as well as the load's inclination regarding the pile's axis. The investigation of the influence of the contact condition at the soil–pile interface shows that the possibility of sliding at the soil–pile interface affects the response of battered piles subjected to loads with low inclination regarding the pile's axis. Copyright © 2008 John Wiley & Sons, Ltd. 相似文献
19.
Rajni Saggu 《Geomechanics and Geoengineering》2015,10(1):10-29
The present work investigates the behaviour of geothermal energy piles in sand subjected to thermal loading and the resulting soil-structure interaction, numerically using the finite element software Abaqus and user-defined material subroutines for soil. The stress-strain response of sand has been simulated using CASM constitutive model based on critical-state soil mechanics. Detailed parametric sensitivity studies have been carried out to understand the effects of different end conditions of the pile, relative densities of the soil, coefficients of lateral earth pressure of the ground, lengths and diameters of the pile, thermal loads, coefficients of friction at the pile-soil interface, critical-state friction angles of soil, thermal conductivity of soil, specific heat of soil and thermal conductivity of the pile on the stress response of soil, deformation of the pile and soil, and strains in the pile. The results show that negative shear stress is generated in the soil at the pile-soil interface. In the pile with both ends restrained the lateral earth pressure coefficient in soil increases due to high radial strain generation. Moreover, the lateral earth pressure coefficient in soil increases with the increase in the thermal load, the coefficient of friction at the pile-soil interface and the critical-state friction angle of the soil. 相似文献