衡重式桩板挡墙上墙土压力模型试验研究

简要介绍了几何相似系数为7的衡重式桩板挡墙模型和多工况模型试验,着重分析了上墙在不同卸荷板尺寸和设置位置及有外荷载工况下对上墙土压力的分布问题。试验结果表明：①板埋深超过某一深度时,并不能有效改善上墙主动土压力的分布情况,反过来说明存在最佳埋深位置。②板宽对卸荷板上表面处的土压力影响较大,但对上墙土压力总体分布趋势没有影响。③填土荷载下,当卸荷板宽度和上墙高比值小于0.4时,上墙土压力接近于朗肯土压力分布;当宽高比大于1.3时,上墙土压力分布更接近于静止土压力。④工程设计时,上墙土压上墙土压力可按公式 计算     

重力式加筋土挡墙的工作性能和土压力计算

“重力式加筋土挡墙”在实际工程中已有不少应用,但由于缺乏对其工作性能的系统研究,目前我国相关规范尚无其设计方法,实际工程中一般根据经验设计,缺乏理论依据。采用FLAC2D程序,模拟一个施工顺序为“先筑墙,后填加筋土”的重力式加筋土挡墙,分墙后填土到墙顶和墙顶堆载完成两个阶段,分析加筋土工格栅对挡墙的水平位移和墙后填土的水平位移、水平应力的影响;土工格栅拉力及拉应变随墙后填土和墙顶堆载的变化。在此基础上,对采用“先筑墙,后填加筋土”工序的重力式加筋土挡墙墙后土压力的计算方法提出了初步建议     

地震条件下悬臂式挡墙主动土压力的极限分析方法

为确定地震条件下悬臂式挡土墙主动土压力,考虑假想坦墙墙背的可能不同位置,给出了墙后填土5种可能的失稳破坏模式;在此基础上,采用拟静力法,基于极限分析上限定理,推导了作用于坦墙墙背上的地震主动土压力计算公式,包括填土性质、填方坡面倾角、踵板长度、墙体高度、水平及竖向地震影响系数等多因素,其中除填土黏聚力与竖向地震影响系数与该土压力呈线性相关性外,其余因素呈非线性影响。实例分析表明,基于本方法地震土压力而计算的墙体抗滑与抗倾稳定系数,多数情况下均比经典的Mononobe-Okabe法略偏大;在填土中存在第二破裂面情况下,以踵板下边缘作为假想墙背端点的计算模式相对略偏不安全;竖直假想墙背模式相应的土压力计算值最小,但相应的墙体稳定系数却不一定最大。     

考虑分层填筑及地应力平衡的挡土墙数值仿真

针对重力式挡土墙墙后分层填土对墙身受力影响的问题,深入研究分析墙背土压力动态变化值及规律性,利用大型通用有限元分析软件ADINA,建立了平面应变单元及墙、土接触单元的有限元计算模型,并且综合考虑墙后回填土Mo-hr-Coulomb材料本构模型,初始地应力场平衡、墙后回填土分层碾压填筑,设置墙、土之间的接触受力进行有限元...     

高填方减载式刚性涵洞受力特性模型试验研究

为了研究高填方减载式刚性涵洞结构的减载效果，利用模型试验分别对减载式刚性涵洞、采用一般减载方法的涵洞和未减载涵洞的涵顶垂直土压力和侧墙水平土压力进行对比分析。在此基础之上，建立了减载式刚性涵洞涵顶垂直土压力理论模型，推得了减载式刚性涵洞涵顶垂直土压力计算式，并将模型试验结果与理论分析结果进行了对比分析。研究结果表明，减载式刚性涵洞不仅能够有效缓解涵顶应力集中，而且与一般减载涵洞相比还能有效减小涵洞侧墙水平土压力；对于减载式涵洞涵顶垂直土压力，理论计算结果与模型试验结果一致且两者相差较小，从而验证了理论模型的适用性和正确性。     

衡重式挡土墙土压力的非线性分析

通过对挡土墙土压力非线性分析方法的研究 ,推导出了衡重式挡土墙土压力计算的数解公式 ,并编制了相应的计算程序 ,一般的直线型墙背挡土墙和折线型墙背挡土墙土压力计算均可作为本文计算公式的特例。通过对一折线型墙背重力式挡土墙的土压力计算与实测结果的比较表明 ,由本文公式所得的解与实测结果很接近。     

考虑挡墙位移效应的被动侧土压力计算方法

挡土结构上土压力的计算是土力学和岩土工程领域的基本研究课题之一。实际工程中的土压力通常是介于主动土压力和被动土压力之间的某一值,墙后填土由于碾压具有较高的密实度。经典的朗肯和库仑土压力理论只能计算极限状态下的土压力,没有考虑挡墙的位移以及剪切过程中密砂的强度从峰值强度降低到残余强度这一强度变化特性对于土压力的影响。给出了考虑挡墙位移效应的被动侧土压力计算方法,该方法能够同时考虑剪切过程中密砂的强度从峰值强度降低为残余强度这一强度变化特性对被动土压力的影响。通过土压力模型试验结果对计算方法进行了初步验证,计算结果和试验结果吻合较好,表明了该方法的有效性。     

高填方减载式刚性涵洞受力特性模型试验研究

为了研究高填方减载式刚性涵洞结构的减载效果,利用模型试验分别对减载式刚性涵洞、采用一般减载方法的涵洞和未减载涵洞的涵顶垂直土压力和侧墙水平土压力进行对比分析。在此基础之上,建立了减载式刚性涵洞涵顶垂直土压力理论模型,推得了减载式刚性涵洞涵顶垂直土压力计算式,并将模型试验结果与理论分析结果进行了对比分析。研究结果表明,减载式刚性涵洞不仅能够有效缓解涵顶应力集中,而且与一般减载涵洞相比还能有效减小涵洞侧墙水平土压力;对于减载式涵洞涵顶垂直土压力,理论计算结果与模型试验结果一致且两者相差较小,从而验证了理论模型的适用性和正确性。     

卸荷式板桩高桩梁板码头结构土压力简化计算

河网地区的淤泥层一般较厚,强度较低,在这些地区新建或扩建码头时需对边坡进行大面积的开挖、换填,工程造价高,采用卸荷式板桩墙高桩梁板码头结构可以很好地解决,但目前关于这种码头结构型式的土压力计算研究非常少。借鉴遮帘板桩码头的土压力计算方法,分析探讨了该新型结构的土压力计算方法。计算中对结构进行分区处理,利用非极限状态土压力理论计算板桩河侧及灌注桩陆侧的土压力,同时考虑土拱效应和卸荷板的卸荷作用,以及平行墙理论,推导计算板桩陆侧及灌注桩河侧的土压力,最后将简化计算结果与离心模型试验结果及有限元数值分析结果进行对比,对比分析表明,该简化计算方法有一定的可行性,可供工程设计参考。     

离心模型试验中微型土压力盒土压力测定

土压力作为离心模型试验中重要的测试参数,受土压力盒的性能、离心机数据采集系统稳定性及外部环境等诸多因素的影响,准确地测量土压力较为困难。土压力盒作为土压力测试元件,其性能对土压力测量准确性有直接影响。为获得较为准确的土压力测试数据,结合离心机数据采集系统,选择两种常见的电阻应变式土压力盒。通过标定试验得出两种土压力盒砂标系数均小于出厂标定系数,Ⅰ型偏小64.75%,Ⅱ型偏小18.77%,Ⅱ型土压力盒与出厂数据的重合度比Ⅰ型好;在研究墙高10～30 m类扶壁式挡墙侧向土压力分布的离心模型试验中,与Ⅱ型土压力盒相比,Ⅰ型存在按出厂系数测得数据失真、灵敏度低和稳定性差的缺点。标定试验和离心试验结果表明,接入自行组建的数据采集系统的Ⅱ型土压力盒比接入静态应变数据采集系统的Ⅰ型土压力盒性能更佳。     

Performance of Counterfort Walls with Reinforced Granular and Fly Ash Backfills: Experimental Investigation

Experimental investigations on model counterfort retaining walls have been carried out to study the lateral movement of the walls and the nature of the failure modes. Mild steel plates of size 1,000 × 900 × 8 mm were used as model retaining walls and were placed in a tank of size 900 × 900 × 670 mm. Ennore sand, obtained from Madras India, and Fly ash, obtained from Panki Thermal Power Plant, India were used as backfill material. Tests were carried out both with and without reinforced backfill. Two types of loading conditions were applied: (i) line load and (ii) uniform surcharge. The shape and size of the failure wedge was studied by observing displacement of bands of colored through a Perspex plate fixed on one side of the tank. Plots of overturning moment against the rotation of a wall top show that with the increase in rotation of wall, the overturning moment decreases. The minimum value of overturning moment is taken as the limiting value. The failure surfaces obtained in different cases are linear and parabolic in shape.     

GPR Signatures of Pipes and Walls with Emphasis on the Effect of Inclined Scanning Trajectory

This study investigates the effects of some commonly encountered constraints such as inclined scanning trajectory, multiple targets in the vicinity and material variation on GPR responses of pipes and walls. Further, the effects of wall inclination and broken walls are also explored in GPR signatures. Interpretation of such signatures in GPR data for archaeological and geotechnical surveys has been a challenge. A physical model was created to simulate buried pipes and walls under controlled conditions by maintaining density and moisture content of the soil medium. The presence of PVC pipes, plastered brick and stone walls buried in the dry sand have been investigated and major observations have been reported. The inclined scanning trajectory on buried pipes shows a change in curvature of hyperbola-like signatures. Inclined transects near the ends of pipes and walls manifest single limb GPR signatures. The responses of multiple pipes and walls show dependence on separation of targets and footprint of an antenna. One can discern stone walls from brick walls by recognizing the diffraction of waves by irregular stones in GPR responses. The signatures of walls differ from pipes with respect to the width of the apex and variation in the intensity in the limb.     

The Effect of the Modular Block Type on Segmental Walls in Soil Reinforced by Geogrid

The behavior of retaining walls in geosynthetic reinforced soil is complex and requires studies and research to understand the mechanisms of rupture, the behavior of the reinforcements in the soil and the behavior of the main elements of the system: reinforcement-wall-soil. Several researches have been done on the use of geosynthetics as backfill massive reinforcement material (experimental studies, numerical analysis, reduced models …). This parametric study was conducted to investigate the influence of modular blocks type on the behavior of reinforced soil segmental walls. A 3.6 m high wall is composed of modular blocks of earth sand reinforced with four geogrid layers was modeled. The properties of materials, the wall geometry, and the boundary conditions will be explained later. The finite difference computer program FLAC3D was used in this study. The results of this numerical study allowed deducing the importance of this parameter. The type of modular blocks has significant effect to decrease the values of lateral displacements of the wall and decreased tensile stress values in the layers of geogrid.

     

不同砂−膨润土垂直防渗墙填筑土料的掺量研究

土?膨润土垂直防渗墙在美国已广泛应用于城市卫生填埋场中,我国的工程中则应用较少。由国产膨润土与原地层土混合在自重应力作用下固结形成的防渗墙,其渗透性、孔隙和压缩性如何受膨润土掺量的影响,针对该一问题,使用福建标准砂模拟原地层,以3种典型膨润土作为混合料,在各掺量下对砂?膨润土填筑土料开展改进柔性壁渗透试验固结试验,研究不同膨润土掺量对填筑料渗透系数k、孔隙率n与压缩系数av影响。结果表明,膨润土和砂形成防渗墙时存在一个对应最小n和av的最优掺量Copt,当膨润土掺量小于等于Copt时,随着掺量增加,填筑料k下降很快,av缓慢减小;当掺量大于Copt后,随掺量上升,k降低速度趋缓,av快速地升高。理论上,膨润土掺入较少时黏土颗粒仅填充砂粒间的孔隙而不影响砂粒堆积,掺量达到一定程度后膨润土使砂粒彼此分离,悬浮在其中,填筑料的孔隙率随掺量而增大,可能是宏观上造成最优掺量产生的主要原因。     

基于GeoStudio的边坡稳定性分析及支护方案选择的理论探讨

本文选择大连市中山区长利巷地区的边坡,通过现场采取岩土样,进行室内试验得出各地层力学物理参数,对边坡进行稳定性分析。针对目前所拥有的模拟软件与方法,分析并筛选出适合该边坡的模拟软件。利用GeoStudio软件建模、模拟,使用Morgenstern-Price方法进行计算,通过分析得到计算结果,该边坡的安全安全系数为1. 127,认为其属于不稳定边坡。对于不稳定边坡,本文对主流的边坡支护方法进行分析筛选,拟采用扶壁式挡土墙支护方案对其进行预防。根据规范设计挡土墙尺寸,并对该挡土墙进行抗倾覆抗滑移验算,得出的验算安全系数满足规范要求,由此可得知该支护方案方法合理,技术可行。     

2D Numerical Simulations of Soil Nail Walls

In practice, numerical simulations of soil nail walls are often carried out to assess the performance and stability. In the present study, implications of the use of advanced soil models, such as hardening soil model and hardening soil with small-strain stiffness model to simulate the behavior of in situ soil on the overall response of simulated soil nail wall have been studied, and compared with respect to the analysis using conventional and most prevalently used Mohr-Coulomb soil model. Further, influence of the consideration of bending stiffness of soil nails on the simulation results has been examined. Results of the simulations indicated that the use of advanced models is desirable for cases of soil nail walls constructed in soft soils and when lateral wall displacements are critical to the adjoining structures. Incorporation of bending stiffness of nails is found important from the consideration of facing failure modes of soil nail walls.     

土钉墙面层土压力的计算分析

在目前的土钉墙设计中,面层通常被当作构造处理而不参与计算,墙后的主动土压力全部由土钉承担。实际上,土钉墙面层承受一部分土（水）压力。文中把土钉墙面层看作是弹性地基上的有限长梁,基于试验,推导了成层地基上土钉墙面层在土钉拉力作用下的挠曲线、转角、弯矩和剪力方程,并与实测数据进行了比较分析,验证了模型的合理性,得到的解析解基本上可以反映土钉墙面层土压力的分布。在此基础上,探讨了不同土性土层中土钉墙面层土压力的分布。面层土压力在土层的分界面上,位移连续,土压力发生突变;软弱土层分布的面层土压力较硬土层为大;上软下硬型较上硬下软的土层分布更能使面层土压力得到充分发挥,同时计算了面层土压力换算成荷载与土钉拉力的比值,其值随着开挖深度的增加越来越大,面层对于土压力的作用随着深度的增加表现得愈加明显,并提出针对不同地区、不同深度和不同土性条件下应给出比值的建议值,以使土钉墙的设计更符合其真实的作用机制,得到的结论和上述比值的计算方法对于进一步研究土钉墙的作用机制及设计中如何充分发挥面层的作用等具有重要的理论意义和实际应用价值。     

Computational simulation of time-dependent behavior of soil–structure interaction by using a novel creep model: Application to a geosynthetic-reinforced soil physical model

In this paper, a model geosynthetic-reinforced soil retaining walls (GRS-RW) is tested by vertically loading it through a rough footing on the top near the retaining wall and the results are simulated by a sophisticated nonlinear Finite Element Method (FEM) having a novel rate dependent constitutive model for both the backfill material and the geosynthetic reinforcement. Usually, polymer geosynthetic reinforcement is known to exhibit more-or-less rate-dependent stress–strain or load–strain behavior due to their viscous properties. The geomaterials (i.e., clay, sand, gravel and soft rock) also exhibit viscous properties. The viscous behavior of geometrials are quite different from that of the polymer based geosynthetic-reinforcements. It has been revealed recently that viscous behavior of sand is a kind of temporary effect, which vanishes with time. So the rate-dependent deformation of backfill reinforced with polymer geosynthetic reinforcement becomes highly complicated due to interactions between the elasto-viscoplastic properties of backfill and reinforcement. In the present study, a scaled model geosynthetic-reinforced soil retaining wall is tested with a vertically loaded rough rigid footing. The results of the model test are simulated by using an appropriate elasto-viscoplastic constitutive model of both sand and geogrid embedded in a nonlinear plane strain FEM.     

Cost Optimization of Reinforced Earth Walls

This paper deals with optimum cost (objective function) design of geosynthetic reinforced earth retaining walls subjected to static and dynamic loading. The design restrictions are imposed as design constraints in the analysis. Choice of the initial designed length and strength of the reinforcement, which are the elements of the design vectors are made in a way that it forms an initial feasible design vector. Thus the problem is one of mathematical programming. The constraints and the objective function being nonlinear in nature, the Sequential Unconstrained Minimization Technique (SUMT) has been used in conjunction with conjugate direction and quadratic fit methods for multidimensional and unidirectional minimization to arrive at the optimal (minimum) cost of the reinforced earth wall. Optimal cost tables are presented for different combinations of the loading and the developed procedure is validated by taking up an example problem. It has been found from the typical example problem that saving of the order of 7–8% can be made over the conventional design of mechanically stabilized earth (MSE) walls with the aid of design charts.     

地下连续墙施工技术

地下连续墙是一种科学先进的施工方法。由于地下连续墙既可用作地下工程的防渗挡土结构墙,又可用作建筑物的承重基础墙,所以已成为地下工程的一种基本的选择方案。根据８个地下连续墙工程项目的施工经验,叙述地下连续墙的导墙、成槽、钢筋混凝土灌注、泥浆处理等施工工艺,并列举了３个工程实例。