考虑渗透系数变化的非饱和土固结性状分析

基于Fredlund非饱和土一维固结理论,研究了有限厚度的表面透水透气、底面不透水不透气的线弹性和黏弹性非饱和土地基在加荷随时间指数性变化时的一维固结特性。分别得到了两类地基在固结过程中同时考虑液相、气相渗透系数非线性变化和仅考虑液相渗透系数变化两种情况下的半解析解答。利用典型算例进行计算,分析了不同情况下两类地基中超孔隙水、气压力消散以及地基固结度随时间的变化规律,并与不考虑渗透系数变化时的半解析解计算结果进行了对比。结果发现：固结过程中渗透系数呈非线性变化;只考虑液相渗透系数变化时,超孔隙气压力的消散变化不大,超孔隙水压力的消散加快;气相渗透系数变化对超孔隙气的消散产生明显影响,对超孔隙水压力消散影响不大。同时考虑液相和气相渗透系数变化时,土体中超孔隙水、气压力的消散均有明显变化,土体固结速度也相应加快;分析结果对非饱和土固结的进一步研究具有重要意义。     

路堤下浆固碎石桩复合地基现场试验研究

浆固碎石桩是一种新型的桩基技术,结合其在宁波绕城高速公路软土路基处理中的工程应用,进行了路堤下浆固碎石桩复合地基现场试验研究,通过实测地基的竖向和侧向变形以及桩、土应力和孔隙水压力,分析了浆固碎石桩复合地基的主要工作性状。试验结果表明,浆固碎石桩复合地基总沉降量小,稳定速度快,工期短;桩顶应力集中现象明显,桩体置换作用明显,同时也发挥了桩间土的承载力特性;孔隙水压力消散速度较快,减小了次固结引起的工后沉降。     

粉喷桩-土工格栅复合地基应力现场测试研究

粉喷桩-土工格栅复合地基使地基水平向和竖直向对抵抗变形的能力得到了增强。针对粉喷桩联合土工格栅加固地基性状进行了现场研究,包括地基的沉降、地土压力、孔隙水压力。根据试验结果,分析了格栅上下土压力的变化、桩土应力比变化、沉降与土压力的关系以及埋于不同深度孔隙水压力变化情况,得到桩-网复合地基受力机理和地基沉降的规律：（1）超孔隙水压力消散慢,但孔隙水压力与上部填土相比变化不大;（2）桩土应力较大,具有均化土压力的作用,同时基于各个断面土压力分布特点,提出了“拱效应”的观点;（3）地基的变形主要是以下卧软土层压缩和桩刺入变形和桩本身的变形,研究结果为进一步的理论研究和工程设计提供了有益的依据。     

基于黏弹性理论的沉桩再固结问题分析

假设桩周土体为饱和黏弹性介质,采用Burgers流变模型进行描述,同时考虑竖向和径向固结,建立了固结控制方程。根据不排水和自由排水情况,将边界条件分为3类并分别得到超孔隙水压力消散的级数解答,该解答能够为孔压静力触探反求固结系数提供一定的理论依据。在此基础上编制了应用程序,对Burgers流变模型中主要参数进行了分析。结果表明,地基表面自由排水、桩端地基不排水条件下,在一定深度以内的桩周土体的固结速度随深度降低,但超过某一范围后固结速度趋于稳定;上、下边界均自由排水条件下,固结速度随深度增加呈现下降、稳定、升高;上、下边界均不排水条件时,孔压消散速度不随深度变化,可简化为本解答仅考虑径向固结的特例。同时土体的流变特性对超孔隙水压力消散的影响比较显著,流变参数G1/1的变化使超孔隙水压力趋于某不为0的定值,且该值随G1/1比值的增大而增加;其他参数不变时,土体剪切刚度比G1/G2的增大会引起孔压消散速度的下降。     

沉桩引起的三维超静孔隙水压力计算及其应用

引入时间、深度参数分析在饱和软粘土中沉桩时引起的超静孔隙水压力,给出了考虑固结效应的超静孔隙水压力的三维解析解;分析了超静孔隙水压力的消散过程中桩周土发生曼德尔效应的时间和区域,提出了在群桩施工过程中土体中的超静孔隙水压力是消散与累加的综合过程,施工完毕后则变为单一的消散的计算模型,并给出计算公式。通过算例,分析了桩群不同桩距、不同入桩顺序对超静孔隙水压力的影响。     

基于非牛顿指数渗流和分数阶Merchant模型的一维流变固结分析

为进一步深入分析饱和黏性土的一维流变固结机制,引入Koeller定义的弹壶元件修正Merchant模型,并以此描述土骨架的黏弹性变形行为;同时引入非牛顿指数渗流模型描述流变固结中的非达西渗流,推导出一个新的饱和黏性土一维流变固结方程,并用隐式有限差分法进行数值求解。通过与有关文献中退化模型结果的对比,验证了有限差分算法的有效性。在此基础上,分析非达西渗流模型参数以及分数阶Merchant流变模型参数对流变固结过程的影响。计算结果表明:分数导数阶数和黏滞系数对地基沉降的影响比对孔压消散的影响更为明显,且分数导数阶数越小或黏滞系数越大,地基沉降需要的时间越长。同时,比起达西渗流,非牛顿指数渗流会延缓地基中的孔压消散,使得沉降发展变慢。另外,考虑流变效应时地基沉降要慢于孔压的消散。     

基于一维和三维固结挤土桩沉降时效计算分析

饱和软黏土地基中的挤土桩,施工引起的桩侧土体超孔隙水压力消散和竖向荷载引起的桩底土体固结是导致其沉降的主要因素。基于三维固结理论,研究了桩侧地基土再固结沉降的变化规律,并从桩-土相互作用的原理出发,结合边界条件,推导出了在桩侧地基土再固结沉降的作用下挤土桩沉降的计算公式。运用太沙基一维固结理论并采用分层总和法计算竖向荷载作用下桩底土体的沉降。提出了饱和软土中挤土桩沉降时效的计算方法。并对工程实例进行了计算分析,其结果符合工程实际沉降规律。     

可液化场地碎石桩复合地基地震动力响应分析

采用砂土液化大变形弹塑性本构模型分析可液化砂土,采用模量随应力与应变变化的等效非线性模型增量形式分析碎石桩,应用FLAC3D有限差分软件对地震动力作用下可液化场地碎石桩复合地基进行三维动力响应分析。模拟分析了在地震作用下碎石桩刚度效应和排水效应对加固处理可液化场地的抗液化效果,从初始小变形到液化后大变形的变形发展,超静孔压累积与消散,及桩与土的变形与应力分配变化等。结果表明,所用模型与方法可合理描述可液化场地碎石桩复合地基在地震作用下场地的动力响应特性和抗液化效果;在地震作用下可液化场地中桩周土体与碎石桩体的竖向应力与水平向剪切应力向碎石桩体集中,竖向有效应力比可降至约1/6～1/3;桩周土体与桩体为非协调变形,剪应变比可达7～10;碎石桩抗液化影响范围约为2.5～3倍桩径,对超过3.5倍桩径范围影响较小;碎石桩与砂土渗透系数比大于100时对降低砂土中超静孔隙水压影响明显;碎石桩对场地的加密效应可显著降低超静孔隙水压力,而碎石桩刚度则对超静孔隙水压力变动影响较小,但有助于减低地面加速度响应峰值。     

考虑桩体固结变形的散体材料桩复合地基固结解析计算

将单个散体材料桩截面和单桩影响范围内的桩周土截面作为一个研究单元考虑,由固结过程中孔隙水排出量等于单元体体积减小量,并引入平均超孔隙水压力的概念,考虑桩体的固结变形,推得散体材料桩复合地基的固结方程。通过等应变假设和初始边界条件,由分离变量法对该固结方程进行求解,得到了桩体和桩间土的平均超孔隙水压力、平均固结度、复合地基整体固结度。通过某工程实例计算,将计算结果与已有解析解进行了比较分析。当散体材料桩复合地基的井径比较大时,两者计算结果十分相近;当井径比较小时,两者差别较大。     

非饱和土二维固结简化计算的研究

针对较高饱和度的非饱和土二维固结问题展开研究。对于较高饱和度的非饱和土,如饱和度 时,将孔隙中气、水近似地看作可压缩的气、水混合流体后,非饱和土近似为土骨架和混合流体的二相土。考虑混合流体的压缩性,建立混合流体的连续方程。联立平衡方程和混合流体的连续方程,求出应力-应变和混合流体压力;再建立水连续方程求解水压力,继而求出气压力、吸力等。算例表明：加载和消散过程中,混合流体与水压力变化基本一致,气压的作用并不大;地基变形过程与高速公路填筑过程中地基变形发生规律一致。说明该简化方法是合理的,并促进了非饱和土固结变形计算走向实用化。     

陆上风轮机梁板基础受力特性简化分析

提出一种多向荷载同时作用下的刚性桩筏基础简化计算方法,基于Mindlin解,分析桩顶面-桩顶面、桩顶面-土表面、土表面-土表面的相互作用关系。推导多向荷载下桩土体系柔度矩阵,得到刚性桩筏基础的受力和变形的关系,通过与有限元对比证明了文中方法的正确性,在此基础上对耦合荷载作用下的风机基础的受力和变形特性进行分析。研究表明,耦合荷载作用下风机基础将会产生竖向不均匀沉降,并会引起桩顶轴力的的巨大的差异。     

Three-dimensional analysis of bearing behavior of piled raft on soft clay

The piled raft has proved to be an economical foundation type compared to conventional pile foundations. However, there is a reluctance to consider the use of piled rafts on soft clay because of concerns about excessive settlement and insufficient bearing capacity. Despite these reasons, applications of piled rafts on soft clay have been increased recently. Current analysis methods for piled rafts on soft clay, however, are insufficient, especially for calculating the overall bearing capacity of the piled raft. This study describes the three-dimensional behavior of a piled raft on soft clay based on a numerical study using a 3D finite element method. The analysis includes a pile–soil slip interface model. A series of numerical analyses was performed for various pile lengths and pile configurations for a square raft subjected to vertical loading. Relatively stiff soil properties and different loading types were also used for estimating the bearing behavior of the piled raft. Based on the results, the effect of pile–soil slip on the bearing behavior of a piled raft was investigated. Furthermore, the proportion of load sharing of the raft and piles at the ultimate state and the relationship between the settlement and overall factor of safety was evaluated. The results show that the use of a limited number of piles, strategically located, might improve both bearing capacity and the settlement performance of the raft.     

考虑基坑开挖影响的群桩基础竖向承载性状数值分析

对土体采用Mohr-Coulomb弹塑性本构模型,用接触面单元模拟桩-土相互作用,利用ABAQUS建立桩筏基础--地基--基坑开挖三维有限元分析模型。对基坑开挖影响下的群桩基础竖向承载性状进行了分析,讨论了桩顶反力分布、桩身轴力、桩侧摩阻力以及开挖引起的桩身水平位移及其弯矩的变化规律,并进行了考虑基坑开挖与不考虑基坑开挖的群桩基础竖向承载性状的对比分析。通过研究,取得了基坑开挖对高层建筑桩筏基础影响的基本认识,这些认识对于改进桩筏基础设计理论有一定的参考意义。     

A simplified analysis method for piled raft and pile group foundations with batter piles

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.     

多向荷载作用下层状地基刚性桩筏基础分析

提出一种多向荷载作用下层状地基中刚性桩筏基础的计算方法。基于剪切位移法,采用传递矩阵形式分析了竖向荷载下桩顶面-桩顶面相互作用;引入修正桩侧地基模量,采用有限差分法分析了水平荷载下桩顶面-桩顶面相互作用;基于层状弹性半空间理论,分析了多向荷载下桩顶面-土表面、土表面-桩顶面、土表面-土表面的相互作用关系。建立了桩土体系柔度矩阵,得到了多向荷载下层状地基中刚性桩筏基础的受力和变形的关系以及桩的内力和变形沿桩身分布规律。通过与有限元对比,验证了该方法的合理性和修正地基模量的优越性,并对多向荷载作用下的桩筏基础进行了计算分析,计算结果表明,水平力将会引起桩筏基础的倾斜。     

A simplified nonlinear analysis method for piled raft foundation in layered soils under vertical loading

This paper presents a simplified nonlinear solution for piled raft foundations in layered soils under vertical loading. Based on the elastic–plastic analysis of a single pile in a layered soil, the shielding effect between a receiver pile and the soil is taken into account to modify the conventional interaction factor between two piles. An approximate approach with the concept of the interaction factor is employed to study the nonlinear behavior of pile groups with a rigid cap. Considering the variation of soil properties, the solution to multilayered elastic materials is used to calculate the settlement of the soil. The interactions between pile–soil–raft are taken into account to determine the stiffness matrix of the piled raft. By solving the stiffness matrix equations, the settlement and the load shared by the piles and raft could be obtained. Compared with results of the available published literatures, the proposed solution provides reasonable results.     

Analysis of piled raft with nodular pile subjected to vertical load using a Winkler model approach

An investigation is made to present analytical solutions provided by a Winkler model approach for analysis of piled rafts with nodular pile subjected to vertical loads in nonhomogeneous soils. The vertical stiffness coefficient along a piled raft with the nodular pile in nonhomogeneous soils is derived from the displacement given by the Mindlin solution for elastic continuum analysis. The vertical stiffness coefficients for the bases of the raft and the nodular part in the nodular pile in a soil are expressed by the Muki solution for the 3‐D elastic analysis. The relationship between settlement and vertical load on the pile base is presented considering the Mindlin solution and the equivalent thickness in the equivalent elastic method. The interaction factor between the shaft of the nodular pile and the soil is expressed taking into account the Mindlin solution and the equivalent elastic modulus. The relationship between settlement and vertical load for a piled raft with the nodular pile in nonhomogeneous soils is obtained by using the recurrence equation of influence factors of the pile for each layer. The percentage of each load carried by both nodular pile and raft subjected to vertical load is represented through the vertical influence factors proposed here. Comparison of the results calculated by the present method for piled rafts with nodular piles in nonhomogeneous soils has shown good agreement with those obtained from the finite element method and a field test. Copyright © 2016 John Wiley & Sons, Ltd.     

高速铁路沉降控制复合桩基的性状试验研究

基于沉降控制设计理念,无砟轨道京沪高速铁路地基处理采用筏板+垫层+疏桩的方法,形成复合桩基以实现有效减少工后沉降和充分利用地基承载力的优化加固方案。为探索该新方法沉降控制机制,选用CFG桩开展了复合桩基现场试验研究,对复合桩基在高速铁路路基填筑、静置、预压卸载过程中的地基沉降变形、桩和桩间土土压力、筏板顶与底部压力进行了长期观测,分析了路基沉降变形、桩-土应力比和荷载分担比以及筏板的受力随填筑高度和固结时间的变化规律。研究表明：筏板＋垫层＋疏桩联合加固地基方案在初期充分发挥了桩间土承载作用,导致桩与桩间土产生差异沉降;随着垫层的调节作用,筏板可集中发挥桩体的承载能力及显著提高桩顶应力集中程度,地基土沉降主要发生在加固区范围内,从而揭示了复合桩基在路基荷载下的承载机制和变形特性。现场试验结果可为指导高速铁路CFG桩复合桩基设计参数的进一步优化提供试验依据。     

竖向荷载作用下桩筏基础可视化模型试验研究

进行了群桩基础可视化模型试验。在试验过程中对各级竖向荷载作用下群桩基础桩、土的变形采用高清晰数码相机拍摄了照片。通过对照片进行后处理分析,得到了桩、土的位移场,也对桩身轴力也进行了量测,在该基础上研究了群桩基础的变形性状和破坏模式,重点分析对比了桩间距和桩长对桩端土体沉降以及桩身侧摩阻力的影响。试验发现,桩距是影响桩土相对滑移量的主要因素,桩距越大,桩身与土的相对滑移量就越大,桩端刺入量也越大。在柔性筏基下,随桩距增加中桩的桩土相对滑移量可能会大于边桩。桩端刺入量是大桩距桩基础主要的沉降构成,以桩端刺入量为研究对象建立一套大桩距基础新的沉降计算理论,似乎值得进一步研究。桩顶向上刺入（可通过设置褥垫层、桩顶预留净空或设置可压缩垫块来实现）有利于桩间土的压密,减小桩端刺入量,甚至改变破坏模式。     

A simplified analysis method for piled raft foundations in non‐homogeneous soils

A simplified method of numerical analysis based on elasticity theory has been developed for the analysis of axially and laterally loaded piled raft foundations embedded in non‐homogeneous soils and incorporated into a computer program “PRAB”. In this method, a hybrid model is employed in which the flexible raft is modelled as thin plates and the piles as elastic beams and the soil is treated as springs. The interactions between structural members, pile–soil–pile, pile–soil–raft and raft–soil–raft interactions, are approximated based on Mindlin's solutions for both vertical and lateral forces with consideration of non‐homogeneous soils. The validity of the proposed method is verified through comparisons with some published solutions for single piles, pile groups and capped pile groups in non‐homogeneous soils. Thereafter, the solutions from this approach for the analysis of axially and laterally loaded 4‐pile pile groups and 4‐pile piled rafts embedded in finite homogeneous and non‐homogeneous soil layers are compared with those from three‐dimensional finite element analysis. Good agreement between the present approach and the more rigorous finite element approach is demonstrated. Copyright © 2002 John Wiley & Sons, Ltd.