Effects of stress conditions on rheological properties of granular soil in large triaxial rheology laboratory tests

In order to study the rheological properties of red stone granular soil,a series of rheological experiments were executed on large tri-axial rheological apparatus.Under 100,200 and 300 kPa confining stress conditions,the rheological tests were carried out.These experiment results showed that the stress conditions,especially the stress level were the critical influencing factors of the rheological deformation properties.Under the low stress level(S=0.1),the granular soil showed the elastic properties,and there was no obvious rheological deformation.Under the middle stress level(0.2<S≤0.6),creep curves showed the linear viscoelastic rheological properties.However,under the high stress level(S>0.8) creep curves showed the non-linear viscous plastic rheological properties.Especially,under the stress level of S=1.0,the accelerated rheological phase of creep curves occurred at early time with a trend of failure.The stress level had obvious effects on the final rheological deformation of the soil sample,and the final rheological deformation increments nonlinearly increased with stress level.The final rheological deformation increment and step was little under low stress level,while it became large under high stress level,which showed the nonlinearly rheological properties of the granular soil.The confining pressure also had direct effects on final rheological deformation,and the final rheological deformation linearly increased with confining pressure increments.

New artificial neural networks for true triaxial stress state analysis and demonstration of intermediate principal stress effects on intact rock strength

Simulations are conducted using five new artificial neural networks developed herein to demonstrate and investigate the behavior of rock material under polyaxial loading. The effects of the intermediate principal stress on the intact rock strength are investigated and compared with laboratory results from the literature. To normalize differences in laboratory testing conditions, the stress state is used as the objective parameter in the artificial neural network model predictions. The variations of major principal stress of rock material with intermediate principal stress, minor principal stress and stress state are investigated. The artificial neural network simulations show that for the rock types examined, none were independent of intermediate principal stress effects. In addition, the results of the artificial neural network models, in general agreement with observations made by others, show （a） a general trend of strength increasing and reaching a peak at some intermediate stress state factor, followed by a decline in strength for most rock types; （b） a post-peak strength behavior dependent on the minor principal stress, with respect to rock type; （c） sensitivity to the stress state, and to the interaction between the stress state and uniaxial compressive strength of the test data by the artificial neural networks models （two-way analysis of variance; 95% confidence interval）. Artificial neural network modeling, a self-learning approach to polyaxial stress simulation, can thus complement the commonly observed difficult task of conducting true triaxial laboratory tests, and/or other methods that attempt to improve two-dimensional （2D） failure criteria by incorporating intermediate principal stress effects.

An anisotropic constitutive model of geomaterials based on true triaxial testing and its application

Series of testing on coarse grained soils were carried out with a true triaxial testing apparatus. The loads were applied from the major principal and minor principal directions, respectively, to simulate the construction and water impounding process of a rock fill dam. The stress and strain relationships induced by the different loading methods were investigated. A remarkable stress-induced anisotropy under complex stress state was observed. Contrary to popular assumptions in traditional numerical analysis and constitutive models, it was found that different elastic modulus and Poisson ratio exist in different principal directions in rock fill dams. From the testing results, an anisotropic constitutive model based on Duncan-Chang nonlinear model is presented to overcome the limitations of axi-symmetric assumptions in conventional triaxial experiments and constitutive models. Both models were then applied in FEM analysis of an under-construction earth core high rock soil filled dam with the focus on hydraulic fracturing. The study reveals the major biases that exist when numerical analysis and constitutive models do not give serious consideration to the intermediate principal stress and anisotropy effects in soil rock built structures.

木质素-稻草改良土的力学特性与修正Duncan-Chang模型

木质素具有胶结土体的作用,稻草纤维也具备提高土体抗剪强度的能力,而采用木质素和稻草共同改良红黏土的研究相对较少。本文通过固结不排水三轴试验,获得了木质素-稻草改良土在不同围压和不同木质素掺量下的应力-应变曲线,并据此研究该改良土的力学特性;同时通过建立修正Duncan-Chang模型,来分析木质素掺量对模型参数的影响。研究结果表明:改良土主应力差随木质素掺量的增加先增大后减小,当木质素的掺量为0.7%时,其到达最大值;改良土初始变形模量Ei、极限偏应力(σ1-σ3)ult、黏聚力c、内摩擦角φ及参数K均随木质素掺量的增加先增大后减小,参数n随木质素掺量的增加而增大,而破坏比Rf受木质素掺量的影响较小。

Dynamic behaviour of weathered red mudstone in Sichuan(China)under triaxial cyclic loading

The construction of a high-speed railway(HSR) in Southwest China is being hindered by a severe shortage of high-quality subgrade materials. However, red mudstone is widely distributed in the Sichuan Basin of China. The ability to use weathered red mudstone(WRM) to fill subgrade beds by controlling its critical stress and cumulative strain would enable substantial savings in project investments and mitigate damage to the ecological environment. To better understand the dynamic behaviour of WRM, both monotonic and cyclic triaxial tests were performed. The evolution of the cumulative strain vs. increased loading cycles was measured. The influences of confining pressure and loading cycles on the dynamic modulus, damping ratio, critical cyclic stress ratio(CSR), and dynamic stress level(DSL) were investigated. The relationship between the CSR and loading cycles under different failure strain criteria(0.1%-1.0%) was analysed. The prediction model of cumulative strain was also evaluated. The results indicated that the shear strength of WRM sufficiently meets the static strength requirements of subgrade. The critical dynamic stress of WRM can thus satisfy the dynamic stress-bearing requirement of the HSR subgrade. The critical CSR decreases and displays a power function with increasing confining pressure. As the confining pressure increases, the DSL remains relatively stable, ranging between 0.153 and 0.163. Furthermore, the relationship between the dynamic strength and loading cycles required to cause failure was established. Finally, a newly developed model for determining cumulative strain was established. A prediction exercise showed that the model is in good agreement with the experimental data.

Shear behavior of coarse aggregates for dam construction under varied stress paths

Coarse aggregates are the major infrastructure materials of concrete-faced rock-fill dams and are consolidated to bear upper and lateral loads. With the increase of dam height, high confining pressure and complex stress states complicate the shear behavfor of coarse aggregates, and thus impede the high dam＇s proper construction, operation and maintenance. An experimental program was conducted to study the shear behavior of dam coarse aggregates using a large-scale triaxial shear apparatus. Through triaxial shear tests, the strain-stress behaviors of aggregates were observed under constant confining pressures： 300 kPa, 600 kPa 900 kPa and 1200 kPa. Shear strengths and aggregate breakage characteristics associated with high pressure shear processes are discussed. Stress path tests were conducted to observe and analyze coarse aggregate response under complex stress states. In triaxial shear tests, it was found that peak deviator stresses increase along with confining pressures, whereas the peak principal stress ratios decrease as confining pressures increase With increasing confining pressures, the dilation decreases and the contraction eventually prevails. Initial strength parameters （Poisson＇s ratio and tangent modulus） show a nonlinear relationship with confining pressures when the pressures are relatively low. Shear strength parameters decrease with increasing confining pressures. The failure envelope lines are convex curves, with clear curvature under low confining pressures. Under moderate confining pressures, dilation is offset by particle breakage. Under high confining pressures, dilation disappears.

温度应力路径对原状海洋土强度特性影响研究

室内温度和海底原位温度的差异导致传统测量所得海洋土物理力学参数存在一定差异。基于温控三轴仪,对我国南海原状海洋土进行了固结不排水剪切试验,实测了海洋土体变、强度、孔压以及模量的变化,探讨温度、温度循环、围压、超固结比等因素对原状海洋土力学性质的影响规律。试验结果表明:升温梯度增大会使正常固结海洋土热固结程度增大,其对应的排水体积和强度也增大;升温对超固结海洋土的排水体积具有增强作用,而温度降低了海洋土的强度;温度循环作用对超固结海洋土的排水体积具有增强作用,其对应的强度也增大;本文试验条件下,当OCR=1时,海洋土25℃下不排水抗剪强度测量结果比5℃下测量结果提高8.0%;当OCR=4时,海洋土25℃下不排水抗剪强度测量结果比5℃下测量结果降低1.9%;经过温度循环5℃—45℃—5℃后的抗剪强度比5℃提高了11.9%;4次或10次温度循环后分别提高了13.8%和17.8%。

土工格室加筋正常固结粉质黏土应力应变响应

土工格室加筋正常固结粉质黏土对工程建设意义重大。基于土工格室与填土的相互作用机制和增量法,采用弹塑性理论、邓肯-张双曲线模型、修正剑桥屈服函数以及剪胀方程,推导了土工格室加筋正常固结黏土的应力应变响应计算模型,进行了土工格室加筋正常固结黏土的三轴固结排水剪切试验,实测不同围压下的应力应变关系,采用三轴试验结果验证了所提理论模型的正确性和可靠性。此外,采用所提理论模型进行了参数敏感分析,研究了填土的力学性质参数、格室的网格尺寸和力学性质参数对于加筋土应力应变响应的影响。研究结论表明,与砂砾料相似,土工格室约束作用对于正常固结黏土的内摩擦角影响较小,而黏聚力有所增加;随着轴向应变的增加或围压的减小,加筋效果逐渐明显;加筋正常固结黏土的强度和刚度随着非线性弹性常数k的增加、强度参数φ的增加和Rf的减小而增大,常数n对于加筋土应力应变响应影响较小。本研究成果可为工程建设提供理论借鉴。

折线应力路径条件下粉质黏土力学特性试验研究

为了探究先基坑开挖后坑边大吨位吊装的特殊应力路径条件下粉质黏土的变形规律、孔压变化以及强度指标,以济南市某隧道附近的粉质黏土原状土样为研究对象,采用K0固结先侧向卸荷后轴向加荷不排水剪切试验,并在卸荷阶段选取3个不同的卸荷比,模拟先基坑开挖后坑边大吨位吊装特殊工况下的应力路径,然后进行等压固结不排水常规三轴剪切试验和K0固结侧向卸荷不排水剪切试验,并对比3种试验结果。结果表明:先基坑开挖后坑边大吨位吊装的特殊应力路径条件下的偏应力-轴向应变试验曲线为非线性曲线,粉质黏土的破坏强度与卸荷量有关,卸荷量越大,则破坏强度越小;减围压阶段产生负孔压,轴向加压阶段孔压随着轴向应变的增加呈先增大后减小的趋势,在同一初始固结围压下,粉质黏土的卸荷比越小,则剪切时产生的最大孔压越大;先基坑开挖后坑边大吨位吊装的特殊应力路径条件下粉质黏土的卸荷比越大,则有效黏聚力越大,有效内摩擦角越小,与等压固结不排水常规三轴剪切试验相比,有效内摩擦角偏小,有效黏聚力随卸荷比的不同而偏大或偏小。

真三轴单面卸荷条件下中间主应力对深埋洞室岩爆影响特征

岩爆灾害已成为国内外深埋洞室建设的重大安全隐患。利用新型真三轴岩爆试验系统,开展了不同中间主应力下“单面侧向卸荷-三向五面受力-竖向持续加载”的室内物理模拟试验,对比分析了不同中间主应力下岩样的弹射破坏过程、破坏形态特征、声发射特性、碎块特征以及弹射动能等变化规律;基于三维离散元理论和多晶建模技术(随机生成Voronoi矿物晶粒),研究了真三轴单面卸荷条件下岩爆“孕育—发生—发展—破坏”全过程及能量演化特征。研究结果表明:不同中间主应力下岩爆弹射破坏过程可概括为颗粒局部弹射、岩石劈裂成板、板折断裂成块及块片全面弹射;其中,岩石劈裂成板是岩爆孕育过程中必然经历的破坏现象。岩样临空面破坏形态具有相似的多元分区破坏特征,即邻近临空面区域产生以张拉破坏为主的劈裂裂缝,远离临空面区域产生以剪切破坏为主的贯穿性斜裂缝。声发射撞击数演化过程可分为相对平稳阶段、快速上升阶段、整体破坏阶段及平静期阶段。随着中间主应力的不断增大,碎块的弹射动能呈增大的变化趋势。岩爆碎块多以粗粒、中粒与细粒碎块为主,且随中间主应力的增加,微粒碎块质量基本不变,细粒、中粒与粗粒碎块质量则呈平稳增加的趋势。利用考虑颗粒矿物成分的晶体尺度精细仿真模型(CSFM)模拟了岩爆“孕育—发生—发展—破坏”全过程,获得了岩样的应力-应变曲线,其变化趋势与室内试验测试结果基本一致且曲线吻合度较好。弹性应变能的演化曲线大致可分为早期增长速率递增阶段、近似线性增长阶段、屈服平台期间增长速率递减阶段及峰后急剧下降阶段。

纤维加筋砂土性能的离散元模拟

采用PFC离散元软件模拟三轴试验,研究固结不排水条件下棕榈纤维增强砂的力学性能。为研究棕榈纤维增强砂的性能,进行了16组PFC三轴试验模拟,并添加1组不加纤维的砂作为对照组,研究了纤维长度为8~20 mm、纤维质量含量为0.2%~0.8%时,纤维增强砂的偏应力、应力路径。试验结果表明,纤维有利于提高砂土的抗剪强度,峰值抗剪强度最高可以增加27%,临界抗剪强度增加21%。因此,纤维对提高砂土的临界抗剪强度起关键作用。砂体的临界抗剪强度与纤维含量和纤维长度均呈正相关,达到临界抗剪强度所需的轴向应变随纤维含量和长度的增加而增加。

考虑中间主应力效应的修正Hoek-Brown真三轴强度准则

为改善Hoek-Brown强度准则未考虑中间主应力对岩石强度的影响,通过岩石真三轴试验结果分析了岩石强度的演化规律,引入中间主应力系数,量化分析主应力系数对岩石真三轴强度的影响,考虑Hoek-Brown强度准则中的参数和岩石应力水平间的关联性,提出了基于拉格朗日插值方法的修正岩石真三轴Hoek-Brown强度准则,分析了其空间包络特征。最后,利用7种岩石的真三轴试验数据与其它3种真三轴强度准则进行最优拟合误差分析,探讨了修正强度准则的合理性。研究结果表明:岩石强度随着最小主应力的增加逐渐增大,随着中间主应力的增加则呈现先增大后减小的变化规律,表现出显著的区间效应;修正强度准则不仅能够继承Hoek-Brown强度准则在子午面上的非线性优点,且能够表征岩石强度在应力空间中的基本特性;线性和非线性插值形式的修正强度准则空间包络面分别为非等边的六棱锥面以及能够满足拉压子午面区间连续光滑要求的圆锥面;修正强度准则能够较好地预测岩石真三轴试验强度,较为合理地反映中间主应力对岩石强度的影响;相比于线性插值形式强度准则,二次插值形式强度准则能够提高岩石强度的预测精度1.2~2.0倍;相较于其他真三轴强度准则,修正强度准则对不同硬脆性岩石的真三轴试验结果均具有良好的强度预测精度,体现了修正强度准则的适用性和可靠性。

棕榈纤维加筋土抗剪强度特性及机理研究

为改善客土喷播后边坡浅层土体强度较低的问题,对棕榈纤维加筋土开展不固结不排水(Unconsolidated Undrained, UU)三轴试验,研究棕榈纤维加筋土在纤维掺量为0.35%、0.55%、0.75%、0.95%,纤维长度为5 mm、10 mm、20 mm、30 mm下不同加筋条件组合对土体抗剪强度特性的影响及其加筋机理.试验结果表明:在粉质黏土中掺入棕榈纤维可以显著提高土体的强度和抗变形能力.极限主应力差在纤维掺量为0.75%、纤维长度为20 mm时达到峰值,较素土提高172.9%;纤维掺量和长度等因素对黏聚力提升显著,较素土提升149.6%.对内摩擦角影响较小,在3°以内变化;对棕榈纤维进行SEM扫描电镜下观察后发现,棕榈纤维表面的沟槽可以增大纤维与土颗粒间的界面摩擦力和咬合作用,从而可以改善土体抗剪强度指标.

风积沙填筑铁路路基累积塑性变形及临界动应力试验研究

目前用于铁路基床的填料大多数为级配优良的填料,而对风积沙作为路基填料在列车荷载作用下的累积塑性变形特性和临界动应力研究不多,但风积沙作为路基填料已在沙漠铁路建设中得到运用。为探究列车荷载作用下风积沙填料填筑铁路路基的累积塑性变形演变特性及临界动应力,考虑围压、动应力幅值、压实系数和含水率等因素的影响,开展一系列动三轴试验。试验结果表明:风积沙累积塑性应变随压实系数、围压的增大而减小,随动应力幅值的增大而增大。以最优含水率为分界点,低于最优含水率时,风积沙累积塑性应变随含水率的增加而减小;高于最优含水率时,风积沙累积塑性应变随含水率的增加而增大。风积沙试样的累积塑性应变曲线可分为:稳定型、临界型和破坏型。根据对累积塑性应变曲线的分类,获得了不同条件下风积沙填料的临界动应力。风积沙临界动应力随围压和压实系数的增大而增大,饱和含水率下风积沙填料的临界动应力明显小于天然含水率和最优含水率下风积沙填料的临界动应力。临界动应力和围压具有较好的线性关系。构建了可考虑围压和含水率影响的风积沙临界动应力经验公式,通过临界动应力公式确定了不同工况下风积沙作为路基填料的适用范围。试验结果可为沙漠铁路的设计、施工以及运营提供经验和理论依据。

加载速率对密砂应力-应变特性影响的试验研究

【目的】砂是一种常见的建筑材料,在水利水电工程、交通、海洋和其他土木工程中应用广泛。在不同的工程应用中,砂土经受不同的加载过程和加载速率。因为加载速率效应,砂在相同幅值荷载作用下产生的变形有一定差异。这项研究旨在深入了解不同应变速率三轴剪切条件下砂的应力应变特性。【方法】采用相对密度为0.9的密砂,开展了一系列三轴固结排水剪切试验,在两种不同围压(750 kPa和2000 kPa)下对试样进行固结后,分别采用三种不同的常应变速率(0.00625%/min,0.0625%/min和0.625%/min)进行应变控制排水剪切。根据试验数据,绘制了应力-应变关系发展曲线,分析了应变速率对砂土偏应力和体积应变演化的影响。【结果】结果表明,在本试验采用的恒定应变速率和围压条件下,密砂在轴向应变约为2%时将发生屈服。屈服前,相同轴应变增量对应的土样偏应力增量和体积应变增量对剪切速率比较敏感,特别是体积应变,即加载应变速率较小时获得的土样剪应力较低,但体积应变(收缩)发展量较大。【结论】在屈服前,砂土的模量随着加载速率的增加而增大;但是屈服后,当加载达到大应变(ε1=15%)条件时,应变率对砂土应力变形的影响不明显。另外,在相同围压下,以不同应变率加载的砂样在加载过程中的应力比(q/p)-偏应变关系呈现出一致性。该研究可以提高对砂土力学特性的认识,并为砂土地基上的结构设计和安全评价提供参考。

不同应力路径下天然沉积软土的应力应变特性

为了揭示应力路径对天然沉积软土应力应变特性的影响,对原状天津软土和衡水湖软土开展物理力学指标、颗粒分析、常规三轴和应力路径三轴试验,系统研究了不同应力路径下天然沉积软土的应力应变特征及其影响因素,得到以下主要结论:结构性和胶结特性改变软土的应力应变特征,排水剪切下结构性和胶结特性较弱的天津软土表现出近似重塑土的应变硬化特征,而结构性和胶结特性较强的衡水湖软土表现出原状土典型的应变软化特征;天然沉积软土具有结构性和胶结特性,可承担一定的拉应力并产生膨胀变形;衡水湖软土黏粒和胶粒含量较高具有明显的胶结特性,在轴向卸载路径下抗剪强度更高且膨胀变形更大。研究结论可为天然沉积软土的设计计算和本构模型研究提供借鉴参考。

含层理砂岩真三轴条件下力学特性研究

为了研究层状砂岩的力学特性与各向异性特征,开展了不同层理倾角与不同中间主应力下的砂岩力学试验。对7种不同倾角(0。、15。、30。、45。、60。、75。、90。)的砂岩进行了3个不同中间主应力水平(10、100、160 MPa)的真三轴试验研究,探讨了层理面倾角对砂岩变形、强度和破坏模式的影响。结果表明,随着中间主应力的增加,砂岩的各向异性逐渐减弱,并趋于各向同性;在高中间主应力的条件下,杨氏模量和破坏角均随各向异性角的增加逐渐增大;峰值强度也受到中间主应力和层面倾角耦合作用的影响;在中间主应力较低的条件下,峰值强度表现出典型的U型变化,随着中间主应力的增加,U型曲线逐渐变得平坦。该研究结果对于指导深埋硬岩工程的设计和施工具有一定的参考意义。

控制吸力下低应力条件的合肥膨胀土抗剪强度试验

膨胀土边坡在变饱和条件下可能发生浅层滑塌失稳。为了研究非饱和膨胀土在低应力条件下的强度特性,采用非饱和三轴仪设置多组不同基质吸力和应力条件,进行合肥膨胀土的三轴剪切试验,对试验数据进行分析。试验结果表明:当膨胀土所受净围压应力不断降低时,其应力-应变曲线会由应变硬化向应变软化过渡;非饱和膨胀土强度随基质吸力增大而增大;浅层膨胀土的抗剪强度会呈现明显降低,具有非线性特点;非饱和膨胀土的黏聚力对抗剪强度影响显著,低应力条件下黏聚力会显著降低,内摩擦角明显增大;净围压应力对低应力段土体强度影响明显,而基质吸力对低应力段土体强度影响较弱。

含碎石芯软黏土复合试样大三轴试验研究

以拟建的某水电站碎石桩地基处理为背景,研发了能提高重塑软黏土固结效率、减小试样扰动的含碎石芯软黏土复合试样的室内试验制样方法,开展了不同围压和碎石芯置换率的复合试样室内大三轴试验研究.研究表明,复合试样在较小围压下表现出应变硬化特性,在较高围压下则基本呈现软化特征,且碎石置换率越小,软化特征越明显,相同围压时,复合试样的初始变形模量随试样面积置换率的增大而增大;在高围压和低置换率时,软黏土碎石芯复合试样的剪切破坏面明显,在低围压和高置换率时,复合试样中部出现较明显的鼓胀现象,碎石芯最大鼓胀量总体随着围压和置换率的提高而增大.规范方法高估了复合试样(地基)的内摩擦角,面积置换率越大,规范计算值与试验结果的差值越大.高围压下传统应力叠加法高估了软黏土振冲置换碎石桩复合地基的承载能力,低估了复合地基的沉降,置换率越高,相同轴向应变时与复合试样大三轴试验的偏应力误差越大.

随机应力循环加卸载三轴试验土的变形稳定状态初探

为研究土在随机应力幅值循环加卸载条件下的应力-应变关系,基于土样全表面变形数字图像测量系统,以福建标准砂和硅微粉为研究对象进行一系列三轴试验。据此分析土样在不同随机应力循环加卸载过程的应力-应变行为,判断其是否达到变形稳定状态,同时与等应力幅值循环加卸载和阶梯应力幅值循环加卸载试验进行对比。结果表明:无论是恒定应力幅值、阶梯应力幅值还是随机应力幅值加卸载循环,当循环次数超过一定次数后,土样逐渐趋于变形稳定状态,且变形稳定状态对应的循环次数值不同;土在受到超过历史最大应力幅值时,应力-应变关系会回到初次单调加载的应力-应变曲线;在最大应力值小于破坏应力的条件下,应力加卸载时间过程幅值的随机特征,如幅值大小和分布对土的应力-应变行为,包括变形稳定状态没有影响。