钢管桩单桩复合地基加固隧道软土地基试验研究

为了对宝兰客运专线王家沟隧道软弱地基进行加固处理,并了解加固后的桩基受力状态,通过现场试验及数值模拟,研究钢管桩单桩复合地基的荷载沉降特性及钢管桩轴力、桩侧摩阻力以及桩身弯矩的变化规律。研究结果表明:由现场试验所得的P-s(荷载-位移)、s-lgt(位移-时间的对数)以及s-lgp(位移-荷载的对数)曲线没有明显可以确定极限承载力的特征点,根据规范采取控制沉降的方式给出极限承载力特征值为200 kPa,并可以此作为设计依据。根据数值模拟中钢管桩的总沉降量以及荷载沉降"归一化曲线",数值模拟可以作为现场试验的必要补充。数值模拟结果显示:桩身轴力呈"D"状分布,最大值为59.8 kN;在距桩顶2 m桩长范围内有负摩阻力产生,其余部位均为正摩阻力,负摩阻力最大值约为130 kPa,正摩阻力最大值约为50 kPa,且桩身中性点并不唯一;桩身上部有弯矩产生,但数值很小,对钢管桩稳定性的影响可以忽略。     

扩底桩抗拔承载特性数值分析

基于通用软件ABAQUS,建立了扩底抗拔桩三维弹塑性有限元模型,通过对模型的计算与分析,探讨了扩底桩的抗拔承载特性。为验证数值模型的可靠性,将数值计算得到的荷载－位移关系曲线与试桩资料进行比较,两者吻合较好,表明本文所建立的模型可较好地模拟扩底抗拔桩的工作性状。通过计算与分析,探讨了扩底抗拔桩的轴力、侧摩阻力分布特征,桩身和扩大头周围土体变形与塑性应变的发展规律,以及扩大头的挤压作用对扩大头周围土体竖向应力的影响。同时,通过变动参数研究了扩大头的形状、土体的性质对扩底桩抗拔承载力的影响,结果表明,扩大头直径和扩大头周围土体的性质对抗拔承载力的影响较大,而扩底高度的影响相对较小。     

现浇X型混凝土桩的荷载传递机理初探

现浇X型混凝土桩技术是河海大学开发研制的用于地基加固处理的一项新技术。在模型试验的基础上,通过有限元方法研究了现浇X型混凝土桩的荷载传递机理,并与模型槽试验结果进行了对比,分析中考虑了桩和土之间的接触和土的非线性。通过数值分析,揭示了X型桩的截面形式对侧摩阻力分布、端阻力发挥的影响。计算结果表明,由于桩的泊松比效应,X型桩截面周边不同位置的侧阻力大小有所不同;X型桩中出现了类似于H型桩的“半封闭土塞”,与圆截面桩相比,桩端附近的侧摩阻力有较明显的增加;X型桩的桩端承载力系数要小于圆截面桩的情况,体现了X型桩截面形状的影响。     

基于桩间土滑动特性的合理桩间距研究

为研究抗滑桩合理桩间距以及荷载传递机制,首先以桩侧摩阻力为拱脚时的破裂面推导出以桩身为拱脚时的破裂角计算公式;然后引入对数螺旋线法确定桩间土体的滑移深度,以土拱效应为基础建立计算模型,求解考虑桩间土体滑移深度的合理桩间距表达式;最后对桩间净距的主要影响因素进行分析,包括滑坡推力、黏聚力、桩截面宽度以及高度。研究结果表明：由桩身和桩侧摩阻力同时作为土拱拱脚更符合实际受力状态,同时求得的土拱拱圈厚度和矢高小于以桩身为拱脚条件下相应值而大于以桩侧摩阻力为拱脚条件下的相应值,并且随桩埋深的增加而增大。     

深厚杂填土场地桩端后注浆钻孔灌注桩承载性状试验研究

针对深厚杂填土建筑场地,给出了1种能准确测定深厚杂填土以下土层的桩侧摩阻及桩端阻力的单桩静载试验装置。基于该试验装置,通过足尺现场试验,研究了竖向荷载作用下2组不同桩长和桩径后注浆灌注桩的承载性能。计算结果表明:直径较大,桩长相对较小的后注浆灌注桩在相同荷载作用下较桩径小和桩长长的桩能更好的控制桩顶沉降量,在相同沉降量条件能承受更大的荷载;同时,和桩径小的长桩相比,更有利于桩侧阻力和桩端阻力的发挥,轴力也能更好的下传递。     

异形效应下Y形桩沉降和单桩极限承载力研究

Y形桩反拱圆弧面侧摩阻力存在不均匀分布现象,侧摩阻力的异形效应导致沉桩过程中的荷载-沉降规律区别于传统桩型,异形效应下的沉降计算单桩极限承载力确定等问题有待研究。通过侧摩阻力、端阻力模型及其产生的附加应力模型,计算不同荷载作用下的桩端沉降,通过荷载-沉降规律预测Y形桩单桩极限承载力。沉降及极限承载力理论计算值与静载试验结果吻合良好。分析了桩长L、外包圆半径R、模板弧度θ、开弧间距s、夹角弧度δ这5个变量对Y形桩沉降及极限承载力的影响,在其他参数不变时,相同桩顶荷载作用下Y形桩单桩沉降随外包圆半径R、开弧间距s、夹角弧度δ、桩长L的增大而减小,随模板弧度θ的增大而增大;Y形桩单桩极限承载力随外包圆半径R、开弧间距s、夹角弧度δ、桩长L的增大而增大,随模板弧度θ的增大而减小。     

湿陷性黄土层桩基侧摩阻力的试验研究

本文依托西安市东北二环立交工程实际,通过现场黄土层浸水试验以及桩基静载试验,研究在湿陷性黄土层中桩基侧摩阻力和桩端阻力的发挥情况、桩基负摩阻力取值问题及桩周土的沉降变化情况,并分析了其实验结果。在总结国内工程界多次试验结果的基础上,给出了湿陷性黄土层负摩阻取值的科学合理方法及应考虑的因素,并分析了影响负摩阻大小取值的因素和引起桩周土沉降差异的因素。研究结果表明：①本工程桩基提供负摩阻力段控制在3～9 m之间,取值建议为-2.0～-5.0 kPa;②桩基上的负摩阻值与特定桩长和地质环境有关,同时与湿陷下沉量及土的粘聚力大小也有关系。从而建议在西安平原地区,黄土层较小时（桩长20 m以上,湿陷层5 m以内）,可不考虑湿陷性对桩基承栽力的影响。本次试验为未来工程实践中湿陷性黄土层的沉降的研究及桩基负摩阻力的取值提供了参考依据和工程实践经验。     

筒型桩靴在饱和砂土中的贯入阻力研究

桩靴贯入阻力的准确预测是自升式钻井平台安全作业的前提。通过小比尺模型试验,研究饱和砂土中桩靴贯入速度对筒型桩靴插桩性能的影响,并基于地基承载力理论提出筒型桩靴贯入阻力的计算方法,进而采用CEL有限元方法模拟筒型桩靴的贯入过程,并与试验结果进行比较。研究发现:当模型试验中桩靴贯入速度在0.1～0.3mm/s时,桩靴的贯入可看作是准静态过程,此时贯入阻力变化不大,采用基于地基承载力理论中的Hansen公式和Vesic公式可较为准确地计算出对应某一深度的贯入阻力;CEL有限元方法可有效模拟筒型桩靴的贯入过程,当桩靴的贯入速度为0.1～0.3mm/s时,数值模拟结果与试验结果吻合较好。     

基于桩土共同作用下的干煤棚桩基有限元分析

干煤棚是火力发电厂中存储煤的一种大型工业建筑,由于需要满足其内部斗轮机作业空间和储煤量,其结构跨度大,高度高。在煤场荷载和上部结构的共同作用下,干煤棚一般采用桩基基础。利用ANSYS有限元软件建立桩土整体模型,分析桩基在上部结构荷载和煤堆荷载作用下的桩-土结构的应力与应变,对比分析了桩-土结构的沉降曲线及桩身内力规律,为今后类似工程的桩基设计提供了重要的参考价值。     

强震状态下黄土中桩基动力性状分析

传统通过p-y曲线法分析强震状态下黄土中桩基动力性状时未进行桩基结构模拟,获取的强震状态下黄土中桩基动力的相关动力参数不准确。本文提出新的强震状态下黄土中桩基动力性状分析方法,依据HS硬化模型设计HSS本构模型,通过模型获取强震状态下黄土中桩基动力的相关参数,以此为基础采用PLAXIS软件构建黄土中桩基有限元模型;通过两种模型从耦合荷载作用下的桩基桩身水平位移响应、桩身内力响应两方面对强震状态下黄土桩基动力性状展开实验分析。实验结果表明,所提方法可对强震状态下黄土中桩基动力性状进行准确分析。     

A new method for estimating driven pile static skin friction with instrumentation at the top and bottom of the pile

A numerical technique is presented to estimate ultimate skin friction of a driven pile using instrumentation installed at the top and bottom of a pile. The scheme is based on an analytical solution of the 1D wave equation with static skin friction and damping along with a genetic algorithm for solution. Specifically, acceleration and strains measured at both the top and bottom of the pile are used to develop an observed Green's function, which is matched to an analytical Green's function, which is a function of secant stiffness and viscous damping. Requiring 1–3 s of analysis time per blow, the algorithm provides a real time assessment of average skin friction along the pile. The technique was applied to four driven piles having ultimate skin frictions varying from 700 to 2000 kN, with the predicted skin frictions generally consistent with measured static load test results.     

装配式人防外墙等效荷载作用下整体性能的分析

运用有限元模拟计算,分析了在等效荷栽及墙外侧土压力的共同作用下,装配式人防外墙结构的整体性能及结构的开口情况、灌注桩的应力分布、装配式墙板的应力以及应变分布等。研究发现：装配式人防外墙结构会产生开口,但开口值较小;桩体的受力比较连续,桩体混凝土沿土压力方向逐渐由受压为主变为受拉为主,墙体的上下端面应力比较集中。结果表明,本文的研究成果对装配式人防外墙结构的设计和施工实践具有指导意义。     

不同厚度饱和砂土中群桩P-Y滞回曲线规律研究

根据Buckingham π定理设计制作直群桩和斜群桩相似模型,通过电磁式振动台试验方法,分别考虑非液化砂土、300 mm和380 mm两种不同厚度饱和砂土,开展在规则正弦波输入下桩土相互作用P-Y滞回曲线规律研究.结果 表明:在非液化砂土中,P-Y滞回曲线的主斜率变化较小,说明在振动输入过程中,桩周土体刚度并未发生显...     

单桩-土-结构振动台试验模型数值计算分析

为研究地震荷载作用下桩基-土-核电结构的抗震性能及土结动力反应规律,对拟开展的地震模拟振动试验模型进行数值计算分析。核电工程结构上部质量大和刚度大,试验模型不同于一般的工程结构,为检验振动台试验模型设计、传感器布设方案,对试验模型进行了数值模拟。数值模拟以单端承桩为研究对象,计算了上部结构质量和刚度变化时,在脉冲荷载及基于RG1.60谱人工合成地震动作用下桩身的地震反应规律。数值模拟表明:在水平地震动作用下,桩身剪力和弯矩包络线呈"X"状分布,桩底和顶处剪力弯矩较大;上部结构质量越大,桩身的剪力与弯矩越大;上部结构的刚度越大,桩身的剪力与弯矩越小;随着上部结构质量的增大和刚度的减小,反弯点逐渐向桩顶移动。桩顶发生最大位移时所对应的桩身挠度随着上部结构质量的增加而增大并且随着上部结构刚度的增大而减小。土层分界面处,桩身内力发生突变。此外,在脉冲荷载输入下,桩身反弯点位置与输入荷载的周期有关。计算结果为振动台试验模型设计提供了理论依据。     

Dynamic pile-soil-pile interaction. Part I: Analysis of axial vibration

Simple methods of analysis are developed for computing the dynamic steady-state axial response of floating pile groups embedded in homogeneous and non-homogeneous soil deposits. Physically-motivated approximations are introduced to account for the interaction between two individual piles. It is found that such an interaction arises chiefly from the ‘interference’ of wave fields originating along each pile shaft and spreading outward. For homogeneous deposits the wave fronts originating at an individual pile are cylindrical and the interaction is essentially independent of pile flexibility and slenderness. For non-homogeneous deposits the wave fronts are non-cylindrical and ray-theory approximations are invoked to derive pile flexibility-dependent interaction functions. Results are presented for the dynamic stiffness and damping of several pile groups, as well as for distribution of the applied load among individual piles. For deposits with modulus proportional to depth, the agreement with the few rigorous solutions available is encouraging. A comprehensive parameter study focuses on the effects of soil inhomogeneity and pile-group configuration. It is demonstrated that the ‘dynamic group efficiency’ may far exceed unity at certain frequencies. Increasing soil inhomogeneity tends to reduce the respective resonant peaks and lead to smoother interaction functions, in qualitative agreement with field evidence.     

Load distribution in large pile groups under static and dynamic loading

Research on the action of pile groups in resisting lateral loading is usually based on analysis, field and centrifuge tests of small pile groups. The interaction between piles in these groups is modelled by modifying the lateral resistance p–y curves developed for a single pile using row dependent reduction factors or a group factor for the entire group to simulate the effect of soil–pile–soil interaction. The modifying factors for the p–y curves and the appropriate group factors for pile groups are based entirely on static tests and there is no direct verification that these factors are appropriate to handle the dynamic loading of earthquake induced ground motions. In this paper we investigate the interaction effects between piles under static and seismic loading using the computer program VERSAT-P3D, which uses an equivalent linear constitutive model for the soil. The analytical procedure is calibrated using data from a static field load test on a single pile. Several pile groups, 2 × 2, 3 × 3, 4 × 4, 5 × 5, 8 × 8, 10 × 10, 10 × 2 and 15 × 2 were analysed for the study. Each group was subjected to static pushover and earthquake loading and the distribution of static and dynamic shear forces at various lateral displacements were evaluated. The study shows that the distribution of load within a pile group under dynamic loading varies significantly from the distribution under static loading and is strongly load intensity dependent. Current practice assumes that the distributions are similar.     

Time-domain solution for transient dynamic response of a large-diameter thin-walled pipe pile

The propagation of stress waves in a large-diameter pipe pile for low strain dynamic testing cannot be explained properly by traditional 1D wave theories. A new computational model is established to obtain a wave equation that can describe the dynamic response of a large-diameter thin-walled pipe pile to a transient point load during a low strain integrity test. An analytical solution in the time domain is deduced using the separation of variables and variation of constant methods. The validity of this new solution is verifi ed by an existing analytical solution under free boundary conditions. The results of this time domain solution are also compared with the results of a frequency domain solution and fi eld test data. The comparisons indicate that the new solution agrees well with the results of previous solutions. Parametric studies using the new solution with reference to a case study are also carried out. The results show that the mode number affects the accuracy of the dynamic response. A mode number greater than 10 is required to enable the calculated dynamic responses to be independent of the mode number. The dynamic response is also greatly affected by soil properties. The larger the side resistance, the smaller the displacement response and the smaller the refl ected velocity wave crest. The displacement increases as the stress waves propagate along the pile when the pile shaft is free. The incident waves of displacement and velocity responses of the pile are not the same among different points in the circumferential direction on the pile top. However, the arrival time and peak value of the pile tip refl ected waves are almost the same among different points on the pile top.     

桩土界面力学行为对桩基动力特性的影响

结合构建的饱和土结构性动力本构模型以及通用有限元程序,以城市高架桥梁建设中常采用的单柱墩基础为原型,建立了摩擦桩-土-结构体系、端承桩-土-结构体系的有限元-无限元计算模型。分完全粘结、滑移无开裂、开裂无滑移、开裂滑移四种情况考察了桩土界面力学行为对两种系统动力反应特性的影响,得出如下结论:无论是端承桩还是摩擦桩,界面力学行为对桩截面的剪应力和桩身水平位移分布形态影响均不大。四种情况中,完全粘结时,摩擦桩在近地表处桩截面剪应力值最大,开裂滑移时最小,而端承桩则刚好相反。水平位移分布均可分为线性增大和加速非线性增大两个阶段,以近地表处为分界点,且均以开裂滑移时最大,完全粘结时最小。界面力学行为极大地改变了端承桩桩身加速度时程的分布形态,但对摩擦桩则几乎没有改变;对于不同界面力学行为,两种桩型在近地表处均出现加速度峰值,完全粘结时值最大,开裂滑移时最小。相比摩擦桩而言,界面力学行为对端承桩的影响要大的多,研究分析时应引起足够的重视。