带压环境下泥浆-泡沫组合改良级配不良砂剪切特性研究

盾构穿越富水砂性地层时易出现排渣不畅或喷涌等风险,仅采用泡沫改良往往无法有效改善级配不良渣土的流动性与抗渗性,归因于泡沫易消散和流失,故须引入膨润土泥浆进行组合改良。正确认识土舱压力环境泥浆-泡沫组合改良级配不良砂土的剪切大变形行为有助于优化满足盾构安全掘进的渣土组合改良方案。因此,开展了泥浆-泡沫组合改良级配不良砂土的加压十字板剪切试验,研究结果表明:在土舱压力环境下,组合改良砂土的初始孔隙比和饱和度随泥浆注入比(bentonite injection ratio,简称BIR)增加而增大,有效应力降低,进而导致峰值强度和残余强度降低;然而剪切强度的剪切率相关性和有效内摩擦角对BIR的敏感性较弱;BIR增加还使大变形后改良砂土的屈服应力有所降低。此外,对比常压下流动性相似的3类不同改良砂土带压剪切大变形行为,表明带压环境下提高BIR或泡沫注入比(foam injection ratio,简称FIR)均可提高孔隙比且减小有效应力,但相较于纯泡沫改良砂土,组合改良砂土具有更低的有效应力和剪切强度。该类级配不良砂土的合适组合改良参数为FIR=20%、BIR=10%~15%。最后,细观成像结果揭示了膨润土对改良砂土剪切强度的双重削弱作用:(1)吸附砂土颗粒表面,降低颗粒间摩擦力;(2)延缓泡沫衰变,使得小粒径气泡较均匀分布于孔隙中,进而有效削弱土骨架强度。

原位测试在岩土工程勘察中的应用研究

盘锦净水厂岩土工程勘察,通过室内试验与原位测试,对表层软塑粉质黏土层提出准确、合理的物理力学参数。对比分析表明:原位测试能较好反映土的实际状态,得出的承载力及抗剪强度指标较室内试验合理。盘锦地区软土勘察,建议采用标准贯入试验为主,十字板剪切试验、静力触探为辅,多种原位测试应相互对比验证,为类似工程项目建设提供借鉴与参考。

广州港南沙港区深厚层软土原位测试方法

广州南沙港区作为广州市重点发展的深水港,其港区内广泛分布深厚软土层,局部软土深度超过30 m。港区内软土层特征主要受两次大规模海侵、海退及珠江水系的影响。上层软土主要由淤泥组成,厚度约10~20 m,夹粉细砂薄层或条带状砂层;下层软土主要由淤泥质土组成,含有机质及腐木碎,厚度约4~8 m。软土参数是影响南沙港区工程建设的重要指标,采用原位测试不易受到影响,可准确呈现软土的力学性质。通过对比分析各种常用的原位测试方法,提出适用于南沙港区深厚软土层的原位测试方法。在工程实践中分别采用不同的原位测试方法获取工程参数,尤其采用不同规格的十字板板头进行十字板剪切试验,旨在为区域内同类软土勘察、设计及施工提供参考。

Study on Shear Strength Characteristics of Columnar Jointed Basalt Based on in-situ Direct Shear Test at Baihetan Hydropower Station

Columnar jointed basalt(CJB) widely distributes in the dam site of the Baihetan Hydropower Station.The columnar joint structure and fracture development of CJB have significant influence on the mechanical properties of rock mass,and the mechanical properties of CJB are of great significance to the Baihetan Hydropower Project.Therefore,in-situ direct shear tests were carried out on ten test adit at different locations in the dam site area to study the shear behavior of CJB.In this study,21 sets of in-situ direct shear tests were conducted for rock types of type Ⅱ_(2),type Ⅲ_(1)and type Ⅲ_(2),with horizontal and vertical shear planes and two different specimen sizes of CJB.Shear strength parameters of CJB were obtained by linear fitting of in-situ direct shear test results based on the Mohr-Coulomb strength criterion.The results indicate that the shear strength parameters of CJB with horizontal shear plane increase as the increase of rock type grade.The shear strength parameters of CJB show obvious anisotropy and the friction coefficient of the horizontal shear plane is greater than the vertical shear plane.The friction coefficient in the horizontal direction of the shear plane is 1.27 times that in the vertical direction of the shear plane.With the increase of rock type grade,the difference of friction coefficient becomes larger.However,the cohesion changes little whether the shear plane is horizontal or vertical.In addition,the size effect of CJB in this area is significant.The shear strength parameters of large size(100 cm × 100 cm) specimens are lower than those of regular size(50 cm × 50 cm) specimens.The reduction of cohesion is greater than that of the friction coefficient.For rock type Ⅲ_(2),the cohesion of large-size specimens is 0.637 of the regular-size specimens.The reduction percentage of the friction coefficient for type Ⅲ_(2)is 1.66 times that of type Ⅲ_(1).The reduction percentage of the cohesion for type Ⅲ_(2)is 1.27 times that of type Ⅲ_(1).The size effect decreases with the increase of rock type grade.The research results of this study can provide an important basis for the selection of rock mechanics parameters in the dam site area of Baihetan Hydropower Station and the stability analysis of the dam foundation and rocky slopes.

基于监测检测数据的真空联合堆载预压软基加固效果分析

以深圳市大空港片区大面积软基处理为例,通过直排式真空联合堆载预压法处理软基的检测及监测数据分析评价地基处理效果,结果表明,采用直排式真空联合堆载预压法处理软基后软土的物理力学性质指标、十字板剪切强度均有提升,地表沉降合理、孔隙水压力逐步消散,平板载荷实验结果满足设计要求。

Revisiting the Bjerrum's correction factor:Use of the liquidity index for assessing the effect of soil plasticity on undrained shear strength

The undrained shear strength （su） of fine-grained soils that can be measured in situ and in laboratory isone of the key geotechnical parameters. The unconfined compression test （UCT） is widely used in laboratoryto measure this parameter due to its simplicity; however, it is severely affected by sampledisturbance. The vane shear test （VST） technique that is less sensitive to sample disturbance involves acorrection factor against the soil plasticity, commonly known as the Bjerrum＇s correction factor, m. Thisstudy aims to reevaluate the Bjerrum＇s correction factor in consideration of a different approach and arelatively new method of testing. Atterberg limits test, miniature VST, and reverse extrusion test （RET）were conducted on 120 remolded samples. The effect of soil plasticity on undrained shear strength wasexamined using the liquidity index instead of Bjerrum＇s correction factor. In comparison with the resultobatined using the Bjerrum＇s correction factor, the undrained shear strength was better representedwhen su values were correlated with the liquidity index. The results were validated by the RET, whichwas proven to take into account soil plasticity with a reliable degree of accuracy. This study also showsthat the RET has strong promise as a new tool for testing undrained shear strength of fine-grained soils.

Determination Method for Shear Strength Parameters of Rock-Soil Mixtures Using Close-Range Photogrammetry and 3-D Limit Equilibrium Theory

Using a combination of close-range photogrammetry and three-dimensional(3-D) limit equilibrium theory, a determination method for the shear strength parameters of rock-soil mixture is presented. A close-range photogrammetry method is used for measurement of the 3-D terrain of the experimental target. Auto CAD Lisp and EXCEL VBA are used to perform 3-D limit equilibrium analysis of the stability of sliding mass and perform backanalysis of shear strength parameters. The presented method was used to determine the shear strength parameters of rock-soil mixtures at the Liyuan Hydropower Station. The 3-D terrain of sliding surface could be measured notably well using of closerange photogrammetry. The computed results reveal that the cohesion and friction angle of rock-soil mixtures were 3.15 k Pa and 29.88o for test A, respectively, and 4.43 k Pa and 28.30o for test B, respectively, within the range of shear strength parameters, as determined by field and laboratory tests. The computation of shear strength parameters is influenced by the mesh grid number, especially the cohesion of the rock-soil mixture. The application of close-range photogrammetry can reduce the siteworks and improve the computational efficiency and accuracy.

Microstructure and mechanical properties of Al-Mg_2Si composite fabricated in-situ by vibrating cooling slope

An innovative semisolid technique termed as vibrating cooling slope(VCS)has been applied to producing in-situ Al-25%Mg2Si(mass fraction)composite.The molten Al-16.5Mg-9.4%Si(mass fraction)alloy with 100°C superheat was poured on the surface of an inclined copper plate(set at 45°inclined angle)while it was vibrated at a frequency of 40 Hz and an amplitude of 400μm.After travelling the length of 40 cm on the slope,the resultant semisolid alloy was cast into a steel mold.For the purpose of comparison,reference composite samples were made by gravity casting(GC)and conventionally still cooling slope casting(CS)methods using the same alloy under identical conditions.The samples were hot extruded at 500°C.It was concluded that the size of Mg2Si particles was decreased by about 50%and 70%for the CS and VCS produced samples respectively when compared to that of the GC produced sample.Despite of their higher porosity contents,both the as-cast and hot-extruded VCS processed samples exhibited higher hardness,shear yield stress(SYS)and ultimate shear strength(USS)values as compared with their GC produced counterparts.These results were attributed to the refined and modified microstructure obtained via this newly developed technique.

惠州港区软土室内与原位十字板剪切试验强度对比分析

原位十字板剪切试验的应用已非常成熟,而室内十字板剪切试验的研究和实际应用尚不多见。依托惠州港区勘察项目对软土进行了室内与原位十字板剪切试验的初步对比研究,得出结论:相同深度处室内试验强度小于原位测试强度,室内测试深度效应较弱而原位测试深度效应更明显;造成室内、原位十字板强度差异的主要原因一是应力状态的差异,二是取样和样品运输过程中土样扰动造成的强度损失;原位十字板抗剪强度与室内测试强度和试验深度相关性良好,惠州港区软土利用室内十字板强度估算的原位十字板强度和实测值平均误差约为12%,可在不具备原位十字板测试条件时通过室内试验间接获得较为可靠的原位十字板强度数据。

基于有效应力原理的泡沫改良粗粒土不排水残余剪切强度计算模型

泡沫常用于土压平衡盾构渣土改良,流动性良好的泡沫改良粗粒渣土有利于盾构进排土顺畅和土舱压力传递,进而避免地层过大变形和失稳。从泡沫改良粗粒土不排水压缩和剪切机理出发,推导了不排水条件下带压泡沫改良粗粒土流动大变形后的残余剪切强度统一理论模型。首先基于理想气体定律和土的有效应力-应变双曲线方程求解不排水一维压缩时的有效应力,然后推导不排水剪切引起的超孔隙压力和残余状态下剪切强度与有效应力的关系式,再构建剪切速率相关的残余剪切强度计算模型。采用不排水加压十字板剪切试验验证了计算模型的准确性,试验值与理论值的平均误差约10%,表明该计算模型可用于确定泡沫改良粗粒土连续流动时的残余剪切强度。最后开展了影响因素分析,竖向总应力增大能提高残余剪切强度,而泡沫注入比增加能降低残余剪切强度;残余状态下流动大变形泡沫改良粗粒土的屈服应力和塑性黏度均与竖向总应力呈正相关,而与泡沫注入比呈负相关。

长江河漫滩软土地基真空联合堆载预压加固效果评价

结合长江河漫滩软土工程特性,通过分析真空联合堆载预压的加固过程,从现场监测数据、原位十字板剪切试验和室内土工试验3个角度,对南京北站迁建工程某施工区域进行了全面的加固效果分析。具体到监测数据方面,地表沉降及孔压数据均表明单真空预压至固结趋稳后再进行堆载可进一步提升土体加固效果;十字板剪切试验结果表明,加固效果随深度递减,与孔压随深度变化规律分析结论一致;室内土工试验数据说明土体物理力学性质在加固后有明显改善。综上所述,真空联合堆载预压对长江河漫滩软土地基加固效果良好,加固效率高,6个月工后固结度可达94.47%,土体强度显著提高。为验证结论的准确性,分别对孔压数据与十字板剪切试验数据、十字板剪切试验数据与室内土工试验数据进行了相互验证,验证结果显示数据较为可靠,加固效果评价的准确度较高。

植物根系分布形态及含根复合土强度特性试验

根系空间分布形态对含根复合土体抗剪强度影响显著。近年来快速发展的透明土试验技术为非嵌入式可视化观测植物根系分布形态提供了技术支撑。基于Carbopol Ultrez10制配成透明黏土材料,开展高羊茅、香根草两种植物根系生长过程中的分布形态观测研究;并与植物在天然砂土与天然黏土中的根系生长长度进行对比分析。继而,开展高羊茅植物根系分别在水平、竖直、倾斜、相交及混合等分布形态下含根复合土体的十字板剪切试验,探讨最优含根量、根系增强效应系数以及表层加筋效应等问题。试验结果表明,透明黏土材料中最优含根量约为0.35%,混合分布形态下根系增强效应最明显,根系增强效应系数约为1.4~1.5。

连云港海相软土不排水强度特征

连云港地区软土为碱性环境下沉积的非均质海积软土,软土抗剪强度具有固有各向异性。采用三轴不固结不排水剪切(UU)试验、无侧限抗压强度(UTC)试验、快剪试验和原位十字板剪切(FVT)试验4种方法,对连云港地区软土的不固结不排水抗剪强度特征进行了研究。结果表明:土体水平剪切面强度最低,竖直面抗剪强度最高;土体制样采用垂直方向的切取试样方式时,土体强度最高。根据三轴UU试验得出的黏聚强度和内摩擦角基于土体单元极限平衡理论恢复了土体剪切破坏时的应力状态,计算出土体实际抗剪强度。三轴UU试验得出的抗剪强度平均值约为13.13kPa,试样破裂面与水平面的夹角在45.1°~45.7°区间最为集中。UTC试验测得的土体平均抗剪强度近似等于三轴UU试验测得的平均抗剪强度。FVT试验测得软土抗剪强度平均值为19.72kPa,与三轴UU试验和UTC试验得出的抗剪强度平均值相比高了约6.60kPa,这种现象与室内试验试样的机械扰动、土体应力状态改变和剪切面特征有关。

利用标准贯入试验确定粘性土的不排水抗剪强度

粘性土的不排水抗剪强度是粘性土的重要力学指标,但目前确定该指标的方法存在着取样扰动或测试深度有限的缺点。通过对马来西亚槟州第二跨海大桥的试验结果研究,综合考虑了SPT的修正方式,不排水抗剪强度的确定方法,粘性土的塑性指数等因素的影响,建立了该地区土层的Cu和SPT之间的经验关系,可为该地区或其它地区的类似工程提供参考。

扁铲侧胀试验求解天津软土不排水抗剪强度

以天津滨海新区软土为研究对象,为了更准确地获得土体不排水抗剪强度Cu,进行了大量的扁铲侧胀试验。并用国内外已有的经验公式,计算了土体的不排水抗剪强度。通过与相邻位置十字板剪切试验结果对比,对已有经验公式在天津滨海新区软土的适用性进行了验证。结果表明,扁铲侧胀试验具有一定的地域性,使用经验公式时需要结合地区土性进行验证或修正。对于天津滨海新区ID≤0.35的软土,采用Lacass和Lunne(1988)提出的计算Cu的公式,当系数取0.17时进行计算适用性较好。

两种方法测定根-土复合体抗剪强度试验对比研究

为了便捷、有效且减少地表破坏面积地原位测定根—土复合体抗剪强度,采用改制后的十字剪切仪在青海大学校内原生植被生长的试验区,分别进行了三种植被覆盖度和三种含水量条件下根—土复合体原位十字剪切试验和室内直接剪切试验。试验结果显示：当土体含水量相同时,室内直剪试验测得的根—土复合体平均粘聚力为20.39～36.49kPa,原位十字剪切试验测得的根—土复合体抗剪强度为35.92～102.36kPa;当植被覆盖度相同时,室内直剪试验测得的根—土复合体平均粘聚力为32.46～23.32kPa,原位十字剪切试验测得的根—土复合体抗剪强度为109.7～68.12kPa。两种试验结果均表现为：根—土复合体的抗剪强度随植被覆盖度的增大而增大,随含水量的增大而减小。原位十字剪切试验测得的根—土复合体抗剪强度值大于直接剪切试验所测得的剪切强度值,平均增幅达到94.23%。两种试验结果产生差异的主要原因是由于剪切过程中剪切方式、破坏面积、受剪根系的数量及破坏程度不同而造成。其中,原位十字剪切试验是在原位不破坏土体结构和根系分布的基础上,将根—土复合体完全剪破,相对更能准确、直观地反映边坡滑坡过程中的变化规律。

滨海吹填场地软土原位剪切强度的试验研究

滨海吹填场地软土普遍具有较高的灵敏性和较低的强度,室内试验的方法较难获得真实的土体剪切强度。为了评价天津滨海吹填场地软土的原位剪切强度特征,针对典型地层开展了静力触探试验、十字板剪切试验、扁铲侧胀试验以及室内不固结不排水剪切试验,分析了多种原位试验与室内试验得到的不排水剪切强度的异同。研究结果表明,该吹填场地软土的不排水强度值为22.6~25.6k Pa;另外,通过对利用以往软粘土原位剪切强度经验公式计算结果的对比分析,证实了软土的原位剪切强度计算公式区域性很强,不能直接套用。最后得出了适合天津滨海场地软土的原位剪切强度公式。

上海软黏土强度固有各向异性

采用室内异形十字板试验对上海淤泥质黏土原生结构导致的不排水抗剪强度的固有各向异性特征进行研究.从基坑中取得筒状土样,然后采用两个具有不同长宽比的矩形板头和三个不同角度(30°,45°和60°)的菱形板头进行室内异形十字板剪切试验,得到了原状土在不同方向破坏面上的不排水抗剪强度.结果表明:由于上海软黏土原生结构的影响,在总应力为零的情况下,其不排水抗剪强度随着破坏面与水平面夹角的增大而增大,即破坏面为水平向时强度最小,竖直向时强度最大.十字板试验结果与直剪试验、无侧限抗压强度试验的结果有很好的一致性.推荐采用Casagrande和Carrillo提出的公式来计算上海软黏土各向异性不排水强度.

宁波地区典型土层地基承载力确定

基于宁波轨道交通1号线和2号线一期工程的静力触探、标准贯入、扁铲和十字板等原位试验数据,采用已有的经验公式预测了宁波地区各典型土层的地基承载力。然后,根据K-S检验法提出了各经验公式预测结果的分布概型及数字特征。在此基础上,通过与宁波地区地基承载力经验值对比,提出宁波地区典型土层地基承载力的建议值。研究结果可对宁波地区岩土工程勘察设计中地基承载力的确定提供参考。

渤海湾北部表层沉积物的物理力学性质

利用在渤海湾北部取得的大量海底表层样、原状箱式样和柱状岩心样品,通过现场十字板剪切试验和室内土工试验得出研究区海底表层土的各项物理力学性质和抗剪强度指标。研究表明,研究区的表层沉积物主要有砂—粉砂—黏土、黏土质粉砂、粉砂、砂质粉砂、粉砂质砂、砂及砾砂7种。根据表层沉积物的不排水抗剪强度,发现研究区中部表层土的抗剪强度明显大于周边区域。