New design equations for estimation of ultimate bearing capacity of shallow foundations resting on rock masses

Rock masses are commonly used as the underlying layer of important structures such as bridges, dams and transportation constructions. The success of a foundation design for such structures mainly depends on the accuracy of estimating the bearing capacity of rock beneath them. Several traditional numerical approaches are proposed for the estimation of the bearing capacity of foundations resting on rock masses to avoid performing elaborate and expensive experimental studies. Despite this fact, there still exists a serious need to develop more robust predictive models. This paper proposes new nonlinear prediction models for the ultimate bearing capacity of shallow foundations resting on non-fractured rock masses using a novel evolutionary computational approach, called linear genetic programming. A comprehensive set of rock socket, centrifuge rock socket, plate load and large-scaled footing load test results is used to develop the models. In order to verify the validity of the models, the sensitivity analysis is conducted and discussed. The results indicate that the proposed models accurately characterize the bearing capacity of shallow foundations. The correlation coefficients between the experimental and predicted bearing capacity values are equal to 0.95 and 0.96 for the best LGP models. Moreover, the derived models reach a notably better prediction performance than the traditional equations.

Methods for Estimating the Ultimate Bearing Capacity of Layered Foundations

The Meyerhof and Hanna′s(M-H) method to estimate the ultimate bearing capacity of layered foundations was improved. The experimental results of the load tests in Tianjin New Harbor were compared with predictions with the method recommended by the code for the foundations of harbor engineering, i.e. Hansen′s method and the improved M-H method. The results of the comparisons implied that the code and the improved M-H method could give a better prediction.

Construction of improved rigid blocks failure mechanism for ultimate bearing capacity calculation based on slip-line field theory

Based on the slip-line field theory, a two-dimensional slip failure mechanism with mesh-like rigid block system was constructed to analyze the ultimate bearing capacity problems of rough foundation within the framework of the upper bound limit analysis theorem. In the velocity discontinuities in transition area, the velocity changes in radial and tangent directions are allowed. The objective functions of the stability problems of geotechnical structures are obtained by equating the work rate of external force to internal dissipation along the velocity discontinuities, and then the objective functions are transformed as an upper-bound mathematic optimization model. The upper bound solutions for the objective functions are obtained by use of the nonlinear sequential quadratic programming and interior point method. From the numerical results and comparative analysis, it can be seen that the method presented in this work gives better calculation results than existing upper bound methods and can be used to establish the more accurate plastic collapse load for the ultimate bearing capacity of rough foundation.

Seismic ultimate bearing capacity of strip footings on slope

The influence of earthquake forces on ultimate bearing capacity of foundations on sloping ground was studied. A solution to seismic ultimate bearing capacity of strip footings on slope was obtained by utilizing pseudo-static analysis method and taking the effect of intermediate principal stress into consideration. Based on limit equilibrium theory, the formulae for computing static bearing capacity factors, Nq, Nc, Nγ, and dynamic bearing capacity factors, Nqd, Ncd, Nγd, which are associated with surcharge, cohesion and self-weight of soils respectively, were presented. A great number of analysis calculations were carried out to obtain the relationship curves of the static and dynamic bearing capacity factors versus various calculation parameters. The curves can serve as the practical engineering design. The calculation results also show that when the values of horizontal and vertical seismic coefficients are 0.2, the dynamic bearing capacity factors Nqd, Ncd and Nγd, in which the effects of intermediate principal stress are taken into consideration, increase by 4%?42%, 3%?27% and 34%?57%, respectively.

非对称破坏模式下临坡地基的Meyerhof承载力新解

利用统一强度理论的平面应变强度方程,综合考虑中间主应力、基础至坡肩的水平距离、边坡高度和基底粗糙情况等因素,提出临坡地基坡面非对称破坏模式和坡底非对称破坏模式,继而建立条形基础下临坡地基新的Meyerhof承载力解答,给出具体应用步骤并开展理论退化分析与对比验证。研究表明:考虑坡后土体强度贡献所提出的非对称破坏模式更符合临坡地基的实际破坏形态;所得临坡地基Meyerhof承载力解答与文献模型试验和数值模拟均吻合良好;中间主应力可明显提高临坡地基的承载力;临坡地基承载力随边坡高度增加先减小后恒定。研究结果合理反映了土体强度的中间主应力效应、破坏模式的非对称性以及基础旁侧土体强度等工程实际情况,对临坡地基优化设计具有一定的理论指导意义。

Slope stability of increasing height and expanding capacity of south dumping site of Hesgoula coal mine:a case study

This paper is devoted to improve the containment capacity of the Hesgoula south dumping site.The general geology of the dumping site was obtained through geological surveys.Physico-mechanical properties of silty clay and bedrock layers that have a large impact on the stability of the dump were measured by direct shear tests and triaxial tests in laboratory.Then ultimate bearing capacity of the substrate were analyzed and calculated.This paper proposed three capacity expansion and increase plans and used GeoStudio software for comparison.Through computation of the stability of the dump site slope after capacity expansion and increase for each plan,the capacity expansion plan was determined.The capacity expansion and increase plan will solve the problem of the current insufficient containment capacity of the Hesgoula south dumping site,which is of great significance for saving mine transportation costs,improving work efficiency,and reducing grassland occupation.

砂土中冲刷条件下三筒基础水平承载特性研究

通过开展小比尺三筒基础承载力模型试验,研究冲刷条件下三筒基础水平承载特性,建立数值模型对模型试验结果进行验证与扩展,分析水平和弯矩荷载下,冲刷率e和相对筒间距S/D对极限承载力的影响,提出三筒基础极限承载力的冲刷修正系数dhe、dme的计算方法;采用固定荷载比方法,通过数值模型计算M-H加载条件下三筒基础的破坏包络线,分析冲刷率e和相对筒间距S/D对复合加载特性的影响,提出冲刷条件下三筒基础M-H破坏包络线公式。研究结果表明:冲刷条件下的三筒基础受水平和弯矩作用直至破坏的过程,经历弹性变形—塑性变形—失稳破坏3个阶段;三筒基础的水平极限承载力随冲刷率e的增大而下降,且下降速率逐渐增大,相同长径比的三筒基础的水平极限承载力随相对筒间距的减小而降低;随着冲刷率e的提高,三筒基础的M-H破坏包络线向内移动,随着相对筒间距S/D增大,归一化破坏包络线呈上凸的趋势。

基于Meyerhof机构的吸力式沉箱基础抗拔承载力极限分析上限解

为了研究吸力式沉箱基础上抗拔荷载作用下的极限承载力上限解,构建出反向Meyerhof破坏模式.根据极限分析上限定理,引入反向地基承载力,基于Meyerhof破坏模式,将原基础下的主动区变为被动区,对数螺旋线方向相反且延伸至沉箱侧壁,建立了相应的机动许可速度场,推导出理论上更为合理的吸力式沉箱基础极限抗拔承载力上限解.分析了上限解与黏聚力、内摩擦角、摩擦系数以及基础下地基反向承载力之间的关系.采用Matlab软件编程计算出上限解,并与文献中的试验数据进行对比分析.结果表明,上限解与试验值的误差最大值为28%,最小值为9%,从而证明了破坏模式的合理性及所提方法的适用性.

非均质黏土地基单桩基础水平极限承载力研究

为减少海上风机长期受到风浪流等水平荷载的影响,利用ABAQUS软件建立非均质黏土单桩基础极限承载力有限元模型,利用温度作为虚拟变量以反映非均质黏性土抗剪强度随深度变化的关系,采用生死单元法进行地应力平衡,并比较有限元得到的水平荷载下单桩基础承载力变化结果与离心机试验结果,以验证其准确性。结合刚性桩与刚柔性桩水平极限荷载下土体失效模式,分析不同长径比、土体弹性模量系数、桩土摩擦因数等参数对单桩基础水平极限承载力影响。结果表明:桩体预埋深度增加后,桩体从刚性桩向刚柔性桩转变,土体破坏模式从楔形、旋转破坏转变为楔形、满流和旋转破坏。土体弹性模量系数对单桩基础水平极限承载力影响较小,长径比和桩土摩擦系数对单桩基础水平极限承载力有较大影响。

双线有轨电车浅埋路基板地基临界载荷计算分析

通过推导双线近邻路基板塑性区深度开展至1/4板宽的临界载荷,调查基础之间距离、埋深、土体重度、内摩擦角和黏聚力对临界载荷的影响。将临界载荷与有限元得到的极限承载力对比,说明国内外路基板地基承载力容许设计值的差异。对某西部城市有轨电车工程的路基板开展设计分析,结果表明,采用单线浅基础临界载荷会高估地基容许设计值,致使设计偏于危险。

基于Meyerhof理论的临坡地基极限承载力简化分析方法

针对现有临坡地基承载力研究方法中采用竖向均布作用力代替基础埋深影响而不能充分考虑埋深内土体抗剪强度贡献的问题,引入Meyerhof理论.首先,基于临坡条形基础地基的工程特点,通过研究其破坏机理,构建出考虑临坡条形基础埋深内土体抗剪强度作用的单侧滑移破坏模式.然后,在此破坏模式研究基础上,基于Meyerhof理论求解基础埋深内土体抗剪强度影响作用的思路,通过引入刚体极限平衡分析方法,导出了能够反映临坡条形基础埋深内土体抗剪强度作用、基础距坡顶距离、基础两侧埋置深度不同以及基础两侧侧壁与土体摩擦作用影响的临坡条形基础地基极限承载力简化计算公式,较已有研究成果计算方法更简便,更具工程适用性.最后,通过工程实例计算分析并与现有研究分析方法对比分析,表明了本研究方法的可行性与合理性.

基于横向变形约束弹性地基梁法的既有锚索桩极限承载力研究

以阿坝州岷江电化公司西侧滑坡前缘既有锚索桩为研究对象,既有锚索桩的极限承载力是滑坡综合治理中需要研究的关键。针对该问题,在桩身检测结果和锚索现场抗拉拔试验结果基础上,根据变形协调原理,对横向变形约束弹性地基梁法在桩锚固段地基水平抗力系数按梯形分布下的计算方法进行推导,并采用这种方法进行1-1'剖面既有预应力锚索桩的内力计算。把锚索极限承载力、既有桩身结构承载力和嵌固段地基强度条件共同作为限制条件,通过反分析方式不断逼近限制条件所对应的滑坡推力界限值,发现该工程中嵌固段地基强度对既有锚索桩的极限承载力起控制作用,并最终确定其极限承载力。该文所采用数据及计算方法可为同类工程研究分析提供参考。

砂性土中海上风电单桩基础水平极限承载力确定方法对比

总结已有的3类单桩基础的水平极限承载力确定方法,分别为极限平衡法、p-y曲线法和定性方法,并结合试验实例研究采用不同方法计算得到的水平极限承载力之间的差异性。结果表明:不同方法求得的结果差异性较大,最大差距可达38.84%。鉴于无统一的方法,以及采用不同方法得到的结果差异性较大,单桩基础的水平极限承载力确定还需要进一步研究。

基于极限抗力的微型群桩承载失效模式研究

基于刚度等效原则推导了微型桩组合结构极限承载力计算方法。结合现场试验及监测成果,采用数值分析方法研究了微型桩组合结构加固边坡的极限承载力及极限破坏模式。研究表明:微型桩间距与结构宽度对微型桩组合结构的极限抗力影响显著,微型桩间距越小,布置越密集,结构宽度越宽,组合结构的刚度越大,其极限抗力越大。微型桩组合结构破坏过程分为:滑面土层剪切破坏、微型桩桩体弯曲破坏、桩-土界面剪切破坏、微型桩桩体拔出破坏4个阶段。微型桩组合结构加固边坡最终的破坏形式是桩体拔出破坏,以桩体发生剪切破坏时的荷载作为极限抗力,低估了其承载能力。联系梁能增加微型桩组合结构的整体刚度,但不会显著提高其极限承载力。

软土地层扩体锚索极限抗拔承载力特性及其改进措施研究

为解决软弱土层中预应力锚索抗拔承载力不足的问题,依托实际工程,通过现场拉拔试验,对比分析扩体锚索和普通锚索的极限抗拔承载力,并研究影响扩体锚索抗拔力的因素,提出相应改进措施,为同类工程提供理论依据与改进思路。结果表明:扩体锚索相比普通锚索的极限抗拔承载力可提高20%~40%,在软土地层具有更好的适用性;提出的改进措施可有效控制软弱土层中锚索抗拔力不足的各种因素,使扩体锚索的极限抗拔承载力提高40%以上;工程应用数据证明,扩体锚索能有效控制基坑位移,具有较好的工程应用效果。

边坡建筑结构设计要点

针对边坡建筑设计中因一侧填土缺失引起基础实际嵌固端、地基承载力和稳定性的变化,本文通过对现行相关规范的解读,并借鉴该类建筑设计较丰富的重庆和贵州等地的经验,按大震不倒的原则对边坡建筑上部结构、基础和地基三部分进行归纳,总结了边坡建筑地基的承载力和稳定性、基础的抗倾覆和抗滑移验算中参数的取值和计算方法。

利用静力触探数据估算钻孔灌注桩承载力的探索

《建筑桩基技术规范》(JGJ 94—2008)、《公路桥涵地基与基础设计规范》(JTG 3363—2019)等现行规范均给出了利用静力触探数据计算预制桩单桩竖向极限承载力标准值的公式,尚缺少利用静力触探数据计算钻孔灌注桩单桩竖向极限承载力标准值的公式。针对北京地区实际情况,根据现行规范混凝土预制桩和泥浆护壁钻(冲)孔桩的土层阻力经验值间的相对关系,初步建立了由静力触探法估算钻孔灌注桩的竖向极限承载力标准值的经验公式,工程实例表明,利用静力触探估算钻孔灌注桩承载力的数值在深部砂层较经验参数查表法有较大提高。

基于结构受力状态理论的群桩基础承载力研究

目的 将结构受力状态理论应用于群桩基础的承载力判定,推广计算群桩基础安全容度和降低材料浪费的方法,为群桩设计提供有力依据。方法 依托沈阳航空航天大学图书馆现场静载试验,通过ABAQUS有限元模拟软件建立群桩基础模型,应用结构受力状态理论分析实测数据与模拟数据,精确判定群桩基础工作过程中的弹塑性分支荷载与失效荷载,并与当前规范理论获取的荷载判定结果进行对比。结果 在考虑群桩效应等不利因素的前提下,所判定的群桩承载力在保证安全的同时,相较于以控制沉降为40 mm方式得到的群桩基础设计荷载提高了21.6%,失效荷载比极限荷载大770 kN。结论 弹塑性分支荷载可以直接作为群桩基础的设计荷载,从极限荷载至失效荷载这一区间经证明群桩结构可以正常工作,可作为群桩基础的安全裕度使用,为研究群桩基础承载力提供了新方法。

岩溶区穿越溶洞桩基极限承载力及破坏模式试验研究

针对岩溶区穿越溶洞桩基承载机理及破坏模式相关问题,开展了穿越溶洞桩基极限承载力及破坏模式室内模型试验,揭示了桩基极限承载力随溶洞高度变化的规律,并将不同高度溶洞下桩基和溶洞顶板的破坏模式进行了分类。根据试验结果给出了穿越不同洞高溶洞桩基的桩身稳定系数Φ。最后对穿越不同洞高溶洞桩基极限状态下端阻分担比及穿越洞高为10d时桩基承载过程中侧阻及端阻分担比的变化曲线进行了分析,结果表明:1)溶洞顶板抗弯能力不足时,若桩-岩界面侧摩阻力较大,且顶板与周围岩体整体性好时发生固支板受弯破坏,整体性差时发生简支板受弯破坏,桩-岩界面侧摩阻力小时,发生剪切破坏或剪切与冲切的组合破坏。2)穿越溶洞桩基发生屈曲的最小洞高为6d,穿越小洞高溶洞桩基在单轴抗压强度小于桩端及桩侧极限阻力时发生桩身材料受压破坏,反之发生桩端基岩破坏。穿越大洞高溶洞桩基在屈曲失稳承载力小于桩端及桩侧极限阻力时发生桩身屈曲失稳破坏,反之发生桩端基岩破坏,且随着洞高增加,桩基屈曲失稳承载力大致呈线性降低。3)穿越溶洞桩基极限承载力取决于桩身材料强度、溶洞高度、桩周岩体强度等多种因素,桩身材料受压破坏、桩基屈曲破坏、桩端基岩破坏3者极限承载力中的最小值即为穿越溶洞桩基极限承载力。4)极限状态下,穿越溶洞桩基端阻分担比随洞高增大而减小,但减小幅度较小;穿越溶洞桩基桩顶荷载越大,端阻分担比越大,侧阻分担比越小。

黏土地基中斜向荷载作用下吸力式沉箱的承载性能试验研究

为了研究黏土地基中斜向荷载作用下吸力式沉箱的承载性能,开展了一系列室内模型试验,分析了斜向荷载作用下吸力式沉箱基础在不同角度和不同加载位置的极限承载力及荷载-位移变化规律.通过ABAQUS建立了吸力式沉箱基础的斜向受荷三维数值模型,分别采用长径比为3和6的模型探究了加载位置对基础极限承载力的影响,进而确定了沉箱基础最优系泊点的位置,并基于极限包络线方法提出了斜向荷载作用下吸力式沉箱基础极限承载力的计算方法.结果表明:当荷载方向与水平向的夹角小于30°时,加载位置深度对基础极限承载力的影响较大;当荷载方向与水平向的夹角大于45°时,加载位置深度对基础极限承载力的影响较小.在基础承载力受加载位置影响较大的斜向荷载角度范围内,随着荷载角度增加,其对应的最优系泊点位置有所上移.