考虑基础刚度影响的风机梁板式桩筏基础模型试验研究

梁板式桩筏基础作为新型风机基础,前景广阔,适当优化结构,可节约成本。采用大型室内模型试验,研究了梁板式桩筏基础在不同筏板刚度情况下的受力变形特性,同时讨论了桩土荷载分担比的关系。研究表明,在工作荷载范围内,适当增大筏板刚度,桩平均轴力增加,外圈桩承担的荷载增大,内圈桩的轴力减小,环梁及肋梁弯矩减小,但继续增加刚度,对桩身轴力、环梁弯矩、肋梁弯矩的影响并不大;随着荷载的增大,土体承担的荷载比逐步增大,趋于稳值。随着梁板式基础刚度增加,基础内外差异沉降减少,但是达到一定刚度后再增加刚度对变形影响较小。梁板式基础刚度的变化会影响基底反力分布的均匀性,且存在一个最优刚度,使基础底部反力分布最为均匀,本次试验中12梁的梁板式基础基底反力比6梁和实体基础更均匀。桩基的分布和梁的分布存在相互影响,改变梁的分布会影响桩顶力,而桩基在梁底下又会使梁的应力产生重新分布。研究成果可为设计桩筏基础提供参考依据。     

冻融条件下模型桩基水平动力试验研究

基于自制的冻土-桩动力相互作用模型试验系统,对-5℃、-3℃及上层融化多年冻土中模型桩基进行了水平向动力试验,主要研究了冻结及上层融化冻土中模型桩基的桩头位移-荷载关系、桩基水平动刚度变化及桩身弯矩分布情况。结果表明：冻土中桩基动力响应特性与土体温度密切相关;正冻土中桩基有较大的侧向刚度,当冻土与桩接触面出现较大间隙时,桩头位移-荷载曲线呈反S形;桩基动力性能随多年冻土温度降低将有所改善;当冻土上部出现融化层时,桩基动响应变化显著,桩头动刚度明显减小,桩基在较小动载下可发生较大侧向位移,同时桩身最大弯矩值较正冻土中偏大,且此弯矩点埋深较大。对于多年冻土区桩基工程,应特别重视夏季上层冻土融化时可能出现的震害。     

不同成桩工艺条件下冻结粉土中基桩承载性状试验研究

桩基础作为冻土工程中最适宜的基础形式,主要采用插入桩、静压桩和灌注桩三种桩型,因其成桩工艺不同对冻土地基及桩基自身造成的差异不一。为研究不同成桩工艺对冻土地基及基桩承载性状的影响,通过开展室内-1.5 ℃条件下单桩静载模型试验,分析在冻结粉土中不同成桩工艺对地温场、桩基极限承载力、桩身轴力以及桩侧摩阻（冻结力）的影响规律。试验结果表明：灌注桩对桩周地温场扰动剧烈,桩侧温度较高,地温变化幅度大。随着桩周土体的回冻,地温逐步降低,其中灌注桩桩侧降温速率最大;在承载力方面,2根灌注桩的极限承载力约为12.8 kN,静压桩为11.6 kN,插入桩极限承载力最小,仅为钻孔灌注桩的2/3。并对比4种不同成桩工艺的基桩在不同荷载条件下对应的沉降量,体现出成桩工艺对基桩沉降造成的差异性;随着桩顶荷载的逐级增加,桩侧摩阻（冻结力）和桩端阻力逐渐发挥作用,桩身上部1/3由于温度较低,致使桩侧摩阻（冻结力）较大,在10 cm深度附近温度最低,使桩侧摩阻（冻结力）达到最大值;并对比4种不同成桩工艺的基桩在荷载5.6 kN下轴力沿桩身的传递情况,发现静压桩更易把荷载传递到冻土区深层地基。     

基于BOTDR的能源桩现场试验与承载特性分析

能源桩集承受荷载和热量交换于一体,受荷载-温度联合作用,其承载性状变化异常复杂。通过上海某能源桩工程现场试验,利用基于布里渊光时域反射技术（BOTDR）的分布式光纤智能感测技术监测桩身轴力和温度变化,获取荷载与温度单一因素及联合作用下桩身轴力及桩侧摩阻力分布曲线,分析了荷载-温度联合作用下能源桩承载性状与荷载传递特征。结果表明：能源桩承载性状与普通灌注桩有一定的差别,桩身温度升高会引起桩身变形,在土体约束作用下产生较大的桩身轴力,其大小与桩身温度变化量近似呈线性关系;荷载-温度联合作用时,桩身轴力远大于受单一因素作用时的桩身轴力,由荷载-温度联合作用引起的轴力增量可达到荷载单独作用时桩身轴力的2倍及以上,同时桩身受温度升高的影响会在较大范围产生桩侧负摩阻力,而荷载作用能够明显缓解桩侧负摩阻力的产生。     

BOTDR分布式检测技术在复杂地层钻孔灌注桩测试中的应用研究

采用布里渊光时域反射技术（BOTDR）对灌注桩进行了分布式应变检测,据此计算桩身位移、桩身挠度、桩身轴力、侧摩阻力和桩端阻力等参量,并在一复杂地质条件场地内两种不同长度和工艺类型的灌注桩内力测试中等到应用,测试表明:灌注桩加载过程中,桩身应变分布在塌孔、夹层及地层分界面等部位出现异常;荷载主要由桩身侧摩阻力承担,桩端阻力在试验荷载内都未发挥;桩基承载能力和特性差异主要由施工工艺及地层条件不同所引起。     

砂土地层中桩基受力特征试验分析

我国长江中下游沿岸地基中分布有较厚的砂土层,砂土层是桩基的良好持力层。该地区砂性土埋藏浅,厚度大,往往夹杂粉土或粉质黏土,一般随深度增大,砂土变密实。已有研究成果中,针对桩身穿过多层砂土条件下桩基承载力的研究较少。砂土地基中打入桩试验结果表明,砂性土的状态对打入式预制桩的施工产生很大的影响,在松散或稍密的砂性土中沉桩一般比较容易,而在中密或密实的砂性土中则较为困难。本文通过某电厂工程灌注桩现场静载试验,研究了砂土地基中桩身沉降随荷载变化规律,分析了桩身轴力随地层深度变化特征及不同土层的桩侧摩阻力。设计钻孔灌注桩桩径为800mm,桩长为47.2m,桩身混凝土强度等级为C35,桩身穿过9层土层,由现场3根桩静载试桩结果可知,荷载与沉降关系呈非线性,Q-s曲线分为弹性阶段、弹塑性阶段和整体破坏3个阶段, 15m深度以下的粉细砂层侧摩阻力对桩身轴力影响较大, 15m以上粉质黏土和淤泥质土对桩轴力影响较小。根据Q-s曲线确定单桩极限载荷约为4800～5400kN,平均值为5201kN,可满足设计要求,地基中下部砂土层承载力较大,砂土侧摩阻力大于黏性土的侧摩阻力,最大可达到70kPa。所得结论可为该类地基进一步的理论研究及工程设计提供有益的参考。     

黄土斜坡桩基竖向荷载传递规律现场试验研究

结合某黄土斜坡桥梁桩基工程,对同一坡度相近位置的两根桩基开展现场试验,研究其在不同竖向荷载工况下的桩身上、下坡面两侧的轴力、桩侧摩阻力及桩侧土压力的传递规律与分布特征。试验表明：桩基荷载传递具有明显的区域性,第1区域是从桩顶至约3倍桩径深度处,此区域上坡面桩侧轴力较下坡面相应位置小,且其轴力随深度递减幅度及侧摩阻力发挥程度均较下坡面桩侧大;第2区域是从约3倍桩径至10倍桩径深度处,桩身上坡面一侧竖向受力减小幅度小于桩基下坡面一侧,但此时下坡面桩侧摩阻力发挥幅度大于桩基上坡面一侧;第3区域是从约10倍桩径直至桩端,该区桩身两侧轴力差异不大,摩阻力发挥幅度相近,荷载平衡协调且向下传递稳定。针对斜坡桥梁桩基上、下坡面两侧所受土压力的不均匀性,对设计桩基竖向承载力进行了一定程度地折减,并对计算公式作了相应修正,研究结论可供类似工程参考、借鉴。     

单桩与带承台单桩荷载传递特性的比较试验

对单桩和带承台单桩进行静载试验比较,桩身与承台下传感器得到了如下荷载传递特性：桩顶荷载分担比随总荷载增加而减小,承台使上部桩身轴力分布平缓,桩侧摩阻力受到削弱,摩阻力传递函数出现软化现象,但同时下部摩阻力发挥得到增强,而桩顶刚度变化不大。这些成果对于桩与承台共同作用特性研究具有重要参考价值。     

考虑加筋与遮帘效应计算群桩沉降的相互作用系数法

群桩中各基桩在地基土中的加筋与遮帘效应是客观存在的,然而,在目前的桩基沉降理论与实践中,相关的研究仍显不足。基于剪切变形法理论,考虑桩的加筋与遮帘效应,求得各基桩在自身桩顶荷载作用下产生的沉降以及其引起相邻桩的附加沉降量,由此提出群桩中任两桩的相互作用系数简化公式,同时,也得到各基桩桩侧及桩端桩-土接触等效弹簧刚度,并基于荷载传递法原理,建立了成层地基条件下各基桩在自身桩顶荷载作用下的桩身位移平衡方程,推导出各土层层顶处桩身沉降、轴力与层底处桩身沉降、轴力之间的递推关系,进而将公式推广到高、低承台群桩基础计算中。工程算例分析表明,用该方法计算有较高的精度,求得的荷载-沉降曲线及两桩相互作用系数与实测值吻合较好;相互作用系数要明显小于弹性理论计算结果。     

基坑开挖时邻近桩基性状的数值分析

基坑开挖时尤为关注的问题是土体侧向移动对邻近桩基的不利影响,土体的侧向移动使邻近桩基产生侧向位移和附加应力及弯矩,甚至可能使上部建筑物功能失效。采用土工有限元软件Plaxis 8.2对内支撑排桩支护基坑开挖过程进行数值模拟,分析了基坑开挖时对邻近桩基的各种影响因素,包括单排桩、双排桩在不同开挖深度、支护桩的刚度、桩基刚度、桩基距基坑开挖面距离、桩身的约束和桩长条件下桩身水平位移和弯矩的变化特性。     

轴向荷载对斜桩水平承载特性影响试验及理论研究

斜群桩受水平荷载作用时,群桩中的基桩受到径向荷载、轴向荷载和弯矩的共同作用。为研究轴向荷载对斜桩水平承载特性的影响,完成了3根单桩以及1组1×2斜桩的大尺寸模型试验。试验结果表明：轴向拉力作用会降低斜桩的水平刚度和极限承载力;而轴向压力作用则会使其水平刚度和极限承载力提高。基于桩侧浅层土体楔形破坏假定,推导了考虑轴向荷载影响的斜桩水平极限土抗力计算公式,提出了桩侧土抗力的p-y曲线方法,并通过模型试验及现场试验验证其合理性。     

兰旗松花江特大桥钻孔灌注桩自平衡试桩研究

在兰旗松花江特大桥航道主墩工程中, 采用直径2 m、长50 m的钻孔灌注桩为基础, 对桩基承载力进行了自平衡测试。选取其中5-1#、6-2#、6-3#试桩实验数据, 从荷载-沉降关系、桩的侧摩阻力分布、桩-土间相对位移关系及端阻力的发挥等方面, 分析了大直径中长灌注桩的承载特性和荷载传递机理以及影响其承载特性的因素。结果表明: 5-1#桩极限承载力为68 917 kN, 6-2#桩极限承载力为62 316 kN, 6-3#桩极限承载力为75 234 kN。     

软土地层桥梁群桩基础桩土共同作用性状的非线性有限元分析

通过对某高速铁路特大桥群桩基础进行三维非线性有限元分析,并结合现场试验得出的规律进行相应的对比分析,研究了软土地层桥梁群桩基础桩身轴力、桩侧摩阻力、基底土体附加应力、孔隙水压力分布、超孔隙水压力消散和群桩基础荷载沉降规律。计算结果表明,基桩所承受的轴力,角桩＞边桩＞中心桩,角桩和边桩的轴力沿桩身减小的幅度较大,而中心桩的轴力沿桩身减小的幅度稍小;各基桩桩侧摩阻力的发挥情况,侧摩阻力值总体上呈角桩＞边桩＞中心桩,相对滑移量基本呈上大下小的形态,即桩身上部桩-土之间产生的相对滑移量较中下部要大;外荷载作用下产生的土体附加应力和超孔隙水压力主要集中在承台底以下土体的一定范围内,其衰减梯度沿深度方向逐渐降低,随着固结时间的延长,群桩基础沉降达到稳定。     

Numerical simulations of landslide-stabilizing piles: a remediation project in Söke,Turkey

A catastrophic landslide following a rainy season occurred in the backyard of a school building in Söke, Turkey. The landslide caused property damage and adversely affected the present forest cover. Immediately after the landslide, double-row stabilizing piles were designed and constructed based on the findings of two-dimensional (2D) finite element (FE) analyses to take an urgent precaution. To remedy the problem, pile displacements were monitored using inclinometers, and it was observed that the measured displacements were greater than the values calculated in the design stage. Accordingly, two different three-dimensional (3D) numerical FE models were used in tandem with the inclinometer data to determine the load transfer mechanism. In the first model, numerical analyses were made to predict the pile displacements, and while the model predicted successfully the displacement of the piles constructed in the middle with reasonable accuracy, it failed for the corner piles. In the second model, the soil load transfer between piles was determined considering the sliding mass geometry, the soil arching mechanism and the group interaction between adjacent piles. The results of the second model revealed that the middle piles with large displacements transferred their loads to the corner piles with smaller displacements. The generated soil loads, perpendicular to the sliding direction, restricted pile deformations and piles with less displacement were subjected to greater loads due to the bowl-shaped landslide. A good agreement between the computed pile displacements and inclinometer data indicates that the existing soil pressure theories should be improved considering the position of the pile in the sliding mass, the depth and deformation modulus of stationary soil, the relative movement between the soil and piles and the relative movement of adjacent piles.     

Non-linear soil–structure interaction in disconnected piled raft foundations

Disconnected piled raft foundations are characterised by no structural connection between the upper raft and the underlying piles, mostly playing the role of settlement-reducers. The resulting raft–pile gap is usually filled with a granular interlayer, through which the loads from the superstructure are transferred to the piles.In this paper, the complex interaction mechanisms involving the foundational components (raft, piles and soil) are numerically investigated by means of 3D finite elements analyses, accounting for soil non-linearity. The main features of the soil–structure interaction mechanisms under purely vertical external loads are explored over a realistic range of raft–soil gaps for different pile configurations, in which the number of piles – i.e. their spacing – is varied. Special attention is also devoted to the structural response of the piles in terms of axial and bending internal stress resultants. In particular, while disconnection beneficially affects the structural pile response, increasing the raft–pile gap tends to reduce the overall settlement/stiffness efficiencies.The numerical results being presented are in substantial agreement with the outcomes from literature small-scale experiments and suggest a number of relevant theoretical inferences.     

Flexural response of piles under liquefied soil conditions

The paper pertains to the development of a generalized procedure to analyze and predict the flexural behavior of axially and laterally loaded pile foundations under liquefied soil conditions. Pseudo-static analysis has been carried out taking into consideration the combined effect of axial load and lateral load. Based on the available literature effect of degradation on the modulus of subgrade reaction due to soil liquefaction has been incorporated in the analysis. The developed program was calibrated and validated by comparing the predicted behavior of the pile with theoretical and experimental results reported in literature. The predicted behavior has been found to be in excellent to very good agreement with the theoretical and observed values in the field, respectively. The present study highlights the importance of considering the axial load from the superstructure along with the inertia forces from the superstructure and the kinematic forces from the liquefied soil in the design of pile foundations in liquefiable areas. The significance of densification of the soil in the liquefiable areas and presence of an adequate top non-liquefied soil cover causing appreciable reduction in deflection and bending moment experienced by the piles has been highlighted.     

大直径深长钻孔灌注桩竖向承载力特性试验研究

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。