Anchoring Depth Research of Anti-Slide Piles of Anchor Bar in Soil

The model test result of earth force in the side of anti-slide pile of anchor bars was introduced.There are three groups of the tests.The loads were on the back side of the slope in two groups.The other one was loaded just behind the pile by the jack.In order to get the force of the soil,some earth-pressure boxes were used to get the earth pressure on the side of the piles.The part of the max pressure and the earth pressure was mainly focused under the slip line

Dynamic response of a slope reinforced by double-row antisliding piles and pre-stressed anchor cables

Large-scale shaking table tests were conducted to study the dynamic response of a slope reinforced by double-row anti-sliding piles and prestressed anchor cables. The test results show that the reinforcement suppressed the acceleration amplification effectively. The axial force time histories are decomposed into a baseline part and a vibration part in this study. The baseline part of axial force well revealed the seismic slope stability, the peak vibration values of axial force of the anchor cables changed significantly in different area of the slope under seismic excitations. The peak lateral earth pressure acting on the back of the anti-sliding pile located at the slope toe was much larger than that acting on the back of the anti-sliding pile located at the slope waist. The test results indicate an obvious load sharing ratio difference between these two anti-slide piles, the load sharing ratio between the two anti-sliding piles located at the slope toe and the slope waist varied mainly in a range of 2-5. The anti-slide pile at the slope waist suppressed the horizontal displacement of the slope surface.

Pre-Stressed Rope Reinforced Anti-Sliding Pile

Pre-stressed rope reinforced anti-sliding pile is a composite anti-sliding structure. It is made up of pre-stressed rope and general anti-sliding pile. It can bring traditional anti-sliding pile＇s retaining performance into full play, and to treat with landslide fast and economically. The difference between them is that the pre-stressed rope will transfix the whole anti- sliding pile through a prearranged pipe in this structure. The working mechanics, the design method and economic benefit are studied. The results show that the pre-stressed rope reinforced anti-sliding pile can treat with the small and middle landslides or high slopes well and possess the notable advantage of technology and economic.

Shaking Table Tests on Bridge Foundation Reinforced by Antislide Piles on Slope

Based on the requirement of seismic reinforcement of bridge foundation on slope in the Chengdu-Lanzhou railway project,a shaking table model test of anti-slide pile protecting bridge foundation in landslide section is designed and completed. By applying Wenchuan seismic waves with different acceleration peaks,the stress and deformation characteristics of bridge pile foundation and anti-slide pile are analyzed,and the failure mode is discussed. Results show that the dynamic response of bridge pile and anti-slide pile are affected by the peak value of seismic acceleration of earthquake,with which the stress and deformation of the structure increase. The maximum dynamic earth pressure and the moment of anti-slide piles are located near the sliding surface,while that of bridge piles are located at the top of the pile. Based on the dynamic response of structure,local reinforcement needs to be carried out to meet the requirement of the seismic design. The PGA amplification factor of the surface is greater than the inside,and it decreases with the increase of the input seismic acceleration peak. When the slope failure occurs,the tension cracks are mainly produced in the shallow sliding zone and the coarse particles at the foot of the slope are accumulated.

Development technology of rigidity-drain pile and numerical analysis of its anti-liquefaction characteristics

Pile foundation is widely used in the offshore engineering. The pile can be seriously destroyed by the soil liquefaction during strong earthquakes. The potentials of liquefaction and damages of pile foundation due to the liquefaction can be reduced by the implementation of the drainage in the liquefiable foundation. A patented pile technology, named rigidity-drain pile, was introduced. The partial section of the pile body was filled by materials with higher penetrability which forms some effective drainage channels in the pile. The principles and construction methods were presented. 3D models for both rigidity-drain pile and ordinary pile were built in FLAC3D code. The dynamic loadings were applied on the bottom of the model. According to the numerical results, in the case of the rigidity-drain pile, the water in the relevant distance range around the pile flows toward the pile drainage, the contour of the pore pressure shows a funnel form. Contrast to the ordinary pile, the rigidity-drain pile can dissipate the accumulated excess pore water, maintain effective stress and obviously reduce the possibility of surrounding soil liquefaction.

圆形抗滑桩-拱形挡土板支挡性能与参数分析

为规避当前施工方法的不足,发展安全、高效和可靠的施工方法。依托东北地区某高速铁路路堑边坡工程,采用适于机械钻孔的圆形抗滑桩代替现行矩形抗滑桩,预制拱形挡土板,本文提出一种新型拱形板-桩墙支挡体系;并构建有限元模型,分析桩长、桩径、桩间距以及拱形挡土板矢跨比对新型拱形板-桩墙支挡体系支护性能的影响;揭示不同参数下桩顶水平位移与桩身内力的变化规律。研究结果表明:桩长与桩身弯矩和剪力大小呈正相关关系,与桩顶水平位移呈负相关关系。桩长超过14 m时,其对桩顶水平位移、桩身弯矩和剪力的影响效应明显减弱;随着桩间距增大,桩顶水平位移增大但变化幅度逐渐减小。拱形挡土板矢跨比增大时,桩顶水平位移、桩身弯矩和剪力均减小。影响拱形板-桩墙体系支挡性能的因素依次为桩间距、桩长、桩径和矢跨比。研究结果为圆形抗滑桩-拱形挡土板支挡体系在实际工程中的应用提供新思路。

降雨作用下抗滑桩与三维土工网垫植草护坡坡体的稳定分析

针对抗滑桩与三维土工网垫植草护坡在降雨作用下的稳定性问题,采用有限元强度折减法,利用ABAQUS建立抗滑桩与三维土工网垫植草护坡坡体的三维有限元模型,以坡底水平位移突变情况作为边坡失稳的判断标准,分别比较了不同工况下护坡安全系数随降雨时长的变化规律,以及降雨作用下抗滑桩桩位、桩长对抗滑桩与三维土工网垫植草护坡坡体的稳定性影响,并与未考虑降雨时的影响规律进行对比。结果表明:降雨时长对三维土工网垫植草工况的边坡稳定性影响较为明显;抗滑桩桩长对边坡稳定性影响较大,桩长宜取8 m;无降雨作用下将桩位置于坡中时边坡整体获得最大安全系数,降雨作用下将抗滑桩置于相对位置(L 0.4=4.8 m)时能够起到更好的抗滑效果;抗滑桩与三维土工网垫植草在降雨作用时加固护坡的效果比无降雨时更好,且优于原边坡。

砂土边坡桩间水平土拱机理与演变规律离散元分析

抗滑桩等非连续支挡结构在边坡工程中依靠土拱效应安全经济地发挥支护功能。鉴于不同类型砂土的力学性质差异较大,为揭示密砂与松砂土质边坡抗滑桩桩间水平土拱机理与演变规律,采用离散元方法(DEM)模拟支挡砂土水平土拱的成拱过程。在传统力链分析的基础上,提出通过筛选高应力颗粒来研究土拱的形成过程,进一步从细观角度对不同工况土拱效应进行分析,以揭示“应力拱”和“位移拱”的演化过程。研究表明:密砂和松砂中的水平土拱的动态演变过程均表现为3个演化阶段,分别对应于密砂和松砂的剪切性状,即应变软化和应变硬化现象,揭示了砂土边坡桩间土拱效应的演变规律。此外,讨论了宏-微观DEM模拟参数对土拱形成过程与土拱效应性能的影响,结果表明拱跨对于荷载传递效率的影响最大。

曲面滑坡条件下h型抗滑桩受力性状模型试验研究

依托公路大型滑坡治理工程,设计物理模型试验装置,设置同一滑面和桩体锚固深度,进行6组h型抗滑桩室内模型试验,分析不同连梁长度及后排桩悬臂段高度(连梁高度)时桩顶位移变化规律、桩身弯矩和桩后土压力分布特征,研究曲面滑坡条件下h型抗滑桩受力性状及其内在机制,并给出桩后滑坡推力抛物线型分布的一般函数表达式。试验结果表明:h型抗滑桩受力过程桩顶水平位移变化表现出较为明显的三阶段特征,桩身弯矩分布呈现正、负交变现象,后排桩桩顶水平位移及桩身弯矩明显大于前排桩;降低后排桩悬臂段高度不影响桩身弯矩分布特征,但对于桩顶水平位移及桩身弯矩量值,后排桩明显减小,前排桩有所增大;增减连梁长度对前、后排桩之间荷载传递与协同受力特性影响显著,使得前、后排桩水平变形及桩身弯矩随之产生变化;连梁正、负弯矩极值均处于连梁端部,相比于连梁长度,连梁弯矩的大小及分布形态受后排桩悬臂段长度的影响更为明显;随着连梁长度的减小或后排桩悬臂段长度的增加,后排桩桩后土压力表现出抛物线型、重心偏下的抛物线型及近似梯形的分布形态。此外,给出的滑坡推力函数表达式能较好的表征其抛物线型分布特征,通过调整合力作用点参数,亦可对滑坡推力近似梯形的分布类型进行描述。

高填方路堤滑坡成因分析及防护对策

以某高速公路互通匝道高填方路堤边坡失稳为例,综合考虑填方区原始地形地貌、地层岩性及施工工艺对路堤边坡稳定性的影响,分析了土−岩二元结构填方边坡的变形特征和破坏机理,认为岩土界面可能为填方边坡的最薄弱层面而非填筑界面。同时,根据滑坡成因分析和稳定性评价结果,借助ABAQUS有限元分析软件对填方边坡的破坏机理做了进一步验证,并对抗滑桩支挡结构的受力状态进行了数值分析。分析可知,滑坡滑面主要在岩土界面处,滑面形态呈折线状;通过开挖台阶、设置宽平台和抗滑桩支挡可有效抑制路堤边坡变形,同时应加强排水;在抗滑桩支挡作用下,高填方路堤边坡潜在滑动面表现为由深层向浅层的演化破坏;滑动面以上桩身应力逐渐减小,在滑面处形成“三角状”高应力区,滑动面以下桩−土接触段桩身应力主要集中在桩前;桩身主要受弯段在潜在滑面以下;桩身主要受推力部位在滑面以上桩长1/5~1/3处,而主要抗力部位在滑面以下桩前部分。

砼结构抗滑桩微形变监测系统的设计与应用

研究砼结构抗滑桩微形变监测系统,对多通道高压激振、拾振等采集电路模块进行设计,提出了“风光互补”的供电和数据的本地、远端冗余存储的系统可靠性保障方案,在内蒙古某露天铁矿边坡滑坡治理工程中的砼结构抗滑桩健康监测应用表明,本文提出的砼结构抗滑桩微形变监测系统能稳定可靠地对砼结构抗滑桩的应力、形变等进行监测,提高了砼结构抗滑桩监测的实时性和科学性。

大型顺层岩石滑坡中多排组合桩加固的数值模拟

为探究大型顺层岩石滑坡的合理支挡防护体系,确保顺层岩石边坡的稳定性,依托安徽某顺层滑坡,基于数值模拟方法,分析“单排桩(或锚拉桩)+h型抗滑桩”联合支护体系在顺层岩石滑坡中的受力特性及支挡防护效果.研究表明:滑坡下部临空面支护与中上部h型桩相关联,且下部单排桩增设锚索后,h型桩桩顶和滑面处位移明显降低,最大弯矩和剪力也有下降趋势;h型桩连梁与后排桩的连接方式对抗滑桩的支护效果有一定影响,固接效果强于铰接,连梁固/铰接方式对h型桩支护结构的弯矩和剪力的影响远小于单排桩有无锚索对h型桩支护结构的弯矩和剪力的影响;“单排桩(或锚拉桩)+h型抗滑桩”联合支护体系可以有效地控制坡体变形,确保顺层滑坡支挡后处于稳定状态.研究成果可为此类岩石边(滑)坡的支护治理提供一定的理论借鉴.

含软弱夹层顺层岩质边坡开挖稳定性分析

以都安高速公路某段含软弱夹层顺层岩质边坡为例,采用极限平衡法对开挖后的边坡进行稳定性分析,基于FLAC3D软件模拟分析边坡分级开挖、分级支护过程中的位移、最大剪切应变增量、应力特征及抗滑桩的承载性能。结果表明:严格条分法的安全系数为1.011,强度折减法安全系数为条分法的97.13%,当考虑岩土体变形时,传统计算方法可能会高估边坡自身的稳定性;边坡采用抗滑桩+框架锚索+框架锚杆的联合支护方式,并进行分步开挖及分级支护,对坡体扰动小,支护效果良好,能很好地控制坡体变形,避免边坡因软弱夹层塑性区贯通而发生失稳破坏。

基于差分法的双排抗滑桩结构内力计算

为研究有连梁双排抗滑桩快速有效的内力计算模型,在对有连梁双排桩进行受力分析的基础上,将有连梁双排抗滑桩结构简化为在桩顶连系梁零弯矩处断开的2根单桩结构,通过对双排桩受力进行叠加得到前后排桩桩顶连梁传递的弯矩与剪力,基于有限差分法建立了有连梁双排抗滑桩受荷段、嵌固段全桩内力计算模型,进而对有连梁双排抗滑桩桩体内力进行了计算。同时,通过大型室内模型试验内力实测结果对所计算结果进行了对比验证。结果表明:(1)模型试验结果与所建计算模型得到的桩顶位移与桩身弯矩值吻合较好,说明简化计算模型具有一定的适用性;(2)二者的后排桩最大弯矩出现位置略有偏差,计算得到的最大弯矩位置更接近实际桩体破坏位置,进一步验证了全桩内力计算模型的可靠性;(3)所建有限差分计算模型避免了将受荷段与嵌固段利用连续条件进行迭代的复杂运算过程,大大提升了计算效率,为实际工程提供了一种快速高效的有连梁双排桩内力计算方法。

岩土成层条件下抗滑桩计算的改进有限差分法

滑坡治理工程中抗滑桩可能布置于层状土层、层状岩层,或岩、土成层等各种地质条件下,现行规范对于该问题建议将成层地基按加权平均法换算成等效的当量地基系数,但对于地层差异性较大的岩土成层地基其适用性有待研究。为解决这一问题,基于Euler-Bernoulli梁理论建立抗滑桩受荷段、嵌固段整体受荷分析模型,采用改进有限差分法提出抗滑桩全桩内力求解的统一矩阵运算式,避免常规有限差分方法将桩身分为受荷段和嵌固段及利用滑面处连续性条件求解的复杂迭代过程;基于2个边坡工程抗滑桩治理案例,证明改进有限差分法对岩土成层条件下抗滑桩分析的可靠性,计算用时仅需1.2 s左右,相比已有方法进一步提高抗滑桩分析设计的计算效率。

单、双排桩支护路堑边坡动力响应特性的振动台试验研究

结合西部艰险山区铁路实际工程背景,开展了El-Centro波作用下单、双排桩支护路堑边坡大型振动台模型试验,基于位移、加速度等参数深入研究了两种模型边坡动力响应特性的差异,并结合快速傅里叶变化(fast Fourier transform,简称FFT)谱探讨了两种边坡出现差异的原因。结果表明:抗滑桩的支护效果和差异均随输入波幅值的增大而逐渐体现;当输入波幅值为0.1g~0.3g时,单、双排桩边坡均处于稳定状态,总体动力响应特性差异较小;当输入波幅值为0.4g时,两边坡动力响应开始出现较大差异,单排桩边坡宏观破坏更明显,坡表位移增大较多,土体损伤累积,非线性特征显现;当输入波幅值为0.5g~0.6g时,两种模型边坡的地震波峰值加速度(peak ground acceleration,简称PGA)放大系数高程效应明显,且均在路堑面和桩后坡面处出现塑性区,抗滑桩的存在有效地抑制了PGA放大系数沿坡面向上的增大趋势和坡表双塑性区的贯通,而单排桩边坡PGA放大效应更明显,塑性区范围更广,深度更大,局部失稳更严重,抗震支护作用相对较弱;引入FFT谱比可知,单、双排桩边坡在5~10 Hz频段振幅放大效应的不同是造成单、双排桩边坡动力响应差异的主要原因;在地震作用下,单排桩边坡破坏历经边坡自稳定→坡表土体塑性变形→边坡局部塌陷溃散3个阶段,双排桩边坡破坏历经前两阶段。

复杂地质条件下抗滑桩水平承载特性影响因素分析

抗滑桩是治理滑坡时经常采用的一种有效的边坡防护工程措施,其水平承载力是评价边坡加固效果的关键。为研究复杂地质条件下边坡抗滑桩的水平承载特性,以卡拉水电站上田镇滑坡体防护工程为例,采用现场试验和数值模拟相结合的方法研究边坡抗滑桩的水平承载特性。基于抗滑桩现场单桩水平静载试验,验证数值计算模型的准确性,在此基础上进行抗滑桩水平承载力影响因素分析。结果表明:前后排桩受水平承载力呈现不均匀性,在相同水平承载力作用下后排桩桩顶最大弯矩大于前排桩桩顶最大弯矩;不同桩布置对群桩水平承载特性影响较大,其中双排交错布置方式桩顶弯矩最小,单排交错次之,双排水平桩顶弯矩最大;相同水平荷载作用下,与1.2 m和1.3 m桩间距相比,1.4 m桩间距的群桩效应较为明显;桩入岩深度对群桩水平承载能力影响较小,只在土-岩体分层界面有明显差异。

抗滑桩极限位移及桩侧阻力分布型式研究

为研究抗滑桩桩侧阻力的分布型式,本文提出了抗滑桩极限位移的概念,并应用平面应变有限元法研究了桩径、桩周土体初始侧向应力及土体力学参数对抗滑桩极限位移的影响;采用蒙特卡罗法对有限元计算成果进行拟合分析,给出了抗滑桩极限位移的计算模型;通过分析笔者在前文给出的抗滑桩极限阻力计算模型,并结合桩阻力与桩位移的关系曲线,给出了确定桩侧阻力分布型式的方法.

硬质岩滑坡深大抗滑桩一体化旋挖成孔技术及应用

硬质岩深大抗滑桩桩孔成孔效率是滑坡灾害防治的难点问题之一。选取川西南典型复杂山区硬质岩滑坡抗滑桩成孔为研究对象,系统分析了裂隙弱发育深部硬质玄武岩地层抗滑桩传统工艺成孔存在的问题,对此设计了9种组合旋挖成孔工艺方案进行现场试桩试验,从钻进效率、技术及经济可行性等方面进行了分析论证。现场试验及分析结果表明:采用“大扭矩截齿筒钻旋挖+扩孔直径差0.4 m”分级扩孔一体化成孔技术在硬质岩地层中钻进效率较高、钻具损耗较低、成本较低,验证了硬质岩抗滑桩高效旋挖分级扩孔技术的可行性和高效性,对比现有人工成孔、冲击钻成孔、旋挖一次成孔等工艺,从安全、效率、成本等方面均得到了极大提升。该技术成功应用于白鹤滩迁建集镇后缘滑坡桩基施工,每延米综合耗时1.43 h,较改进前旋挖一次成孔效率提升3倍,成本降低了60%。该技术为复杂地质条件下水敏型、震敏型硬质岩滑坡抗滑桩快速成孔施工提供了高效、可行的技术方案。

大直径盾构切穿抗滑桩对堤岸的变形影响分析

为研究大直径盾构切穿护岸抗滑桩对堤岸的扰动影响,确保盾构隧道穿越过程中大堤的安全性与稳定性,采用有限元分析软件建立了隧道-桩基-堤岸三维数值模型,重点分析了盾构切穿施工时堤岸及桩体的变形规律,并对比了不同盾构推力下桩体的变形差异.研究结果表明:盾构切削护岸抗滑桩将导致大堤迎水面边坡产生较大扰动,坡顶出现最大纵向位移,被切桩周围土体出现明显下沉;在盾构推力以及迎水面滑坡推力的双重影响下,抗滑桩以挠曲变形为主,整体形成一条倾斜的“S”形曲线,盾构刀盘抵近桩体时的抗滑桩挠曲变形最为明显;盾构推力由0.7倍静止土压力增至0.9倍,桩身水平位移大幅增加,盾构刀盘抵近桩基时的桩底位移增幅高达162%.综上可知,盾构切削穿越抗滑桩时应严格控制推进速度、泥水压力等施工参数,以减小盾构推力对堤岸及桩体的不利影响.