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复杂应力条件下饱和松砂孔隙水压力增长特性的试验研究 总被引:9,自引:3,他引:6
针对福建标准砂D1=30%,在三向非均等固结条件下,利用新研制的土工静力一动力液压三轴一扭转多功能剪切仪针对多种不同初始主应力变化方式进行了循环扭剪试验,讨论了初始主应力方向变化等初始固结条件对饱和松砂不排水条件下孔隙水压力变化规律的影响,对循环扭剪过程中主应力方向与中主应力系数的变化进行了分析,给出了孔隙水压力随循环次数的变化规律。结果表明:分别以最大孔隙水压力和液化破坏时循环次数归一化后的孔隙水压力比和循环次数比之间的关系依赖于循环剪应力幅值和初始主应力方向。而归一化后的孔隙水压力比与广义剪应变之间的关系和循环剪应力幅值、初始主应力方向无关,可以统一地采用双曲线模式表达,其中的两个待定参数依赖于初始主应力方向。 相似文献
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利用“土工静力 动力液压 三轴扭转多功能剪切仪”,针对采用初始成样含水率为0和10%夯击法制备重塑饱和粉土试样,在初始平均主应力为100 kPa,初始中主应力系数为0.5,初始偏应力比为0.433,初始主应力方向角分别为0°、30°、45°的条件下完成非均等固结,然后保持平均主应力和中主应力系数恒定进行不排水循环扭剪实验。着重探讨初始成样含水率和初始主应力方向对粉土动力剪切变形、强度及孔压变化等特性的影响。实验结果表明:初始主应力方向对重塑粉土的变形与强度特性的影响程度有所不同;初始成样含水率对饱和重塑粉土的动力变形及强度特性具有显著影响。 相似文献
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利用“土工静力 动力液压 三轴扭转多功能剪切仪”,针对采用初始成样含水率为0和10%夯击法制备重塑饱和粉土试样,在初始平均主应力为100 kPa,初始中主应力系数为0.5,初始偏应力比为0.433,初始主应力方向角分别为0°、30°、45°的条件下完成非均等固结,然后保持平均主应力和中主应力系数恒定进行不排水循环扭剪实验。着重探讨初始成样含水率和初始主应力方向对粉土动力剪切变形、强度及孔压变化等特性的影响。实验结果表明:初始主应力方向对重塑粉土的变形与强度特性的影响程度有所不同;初始成样含水率对饱和重塑粉土的动力变形及强度特性具有显著影响。 相似文献
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主应力轴持续旋转条件下饱和松砂的振动孔隙水压力特性 总被引:2,自引:0,他引:2
利用新研制的“土工静力-动力液压三轴-扭剪多功能剪切仪”,针对福建标准松砂,在三向非均等固结条件下,进行了能够模拟海洋波浪荷载作用下主应力轴连续旋转的循环耦合剪切试验。通过试验着重探讨了初始主应力方向、振动过程中主应力方向连续变化对不排水条件下砂土的振动孔隙水压力增长特性的影响。实验研究表明:在振动过程中主应力轴连续旋转的条件下,初始主应力方向对砂土的动孔压比与振次比之间关系具有显著的影响,随着初始大主应力与竖向之间夹角的增大,动孔压比的增长速度明显加快,具有较好的规律性;归一化孔压比与广义剪应变之间的关系基本上与初始主应力方向角和振动剪应力幅值无关。 相似文献
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复杂应力条件下饱和松砂单调与循环剪切特性的比较研究 总被引:4,自引:0,他引:4
本文利用大连理工大学新引进与开发的“土工静力-动力液压-三轴扭转多功能剪切仪”,针对福建标准砂,在不排水条件下同时进行了单调剪切试验与循环剪切试验,进而对其进行了对比分析。通过比较表明,应力-应变关系的应变软化和硬化特性与流滑变形和循环流动特性密切相关,当循环剪切应力水平高于单调剪切过程中应变软化阶段最小强度时将会发生流滑变形。无论在单调剪切中,还是在循环剪切中,稳定状态时的有效偏应力比随着大主应力方向与竖向之间夹角的增大而减小,在中主应力系数相同的条件下,循环剪切中呈现显著剪胀时的有效偏应力比和最终稳定状态时的有效偏应力比峰值分别与单调剪切中达到相变状态时的有效偏应力比和最终稳定有效偏应力比基本上一致。然而不排水条件下单调与循环剪切过程中孔隙水压力的增长特性却并不相同,循环剪切中的最大孔隙水压力随着初始主应力方向角的增大而减小,单调剪切中的最大孔隙水压力却随着主应力方向角的增大而增大。 相似文献
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利用土工静力-动力液压三轴-扭转多功能剪切仪,针对相对密度Dr=30%的福建标准砂,进行了不排水条件下的单调剪切试验。在剪切过程中,控制平均固结应力和中主应力系数保持不变,而总主应力方向不固定。与剪切过程中总主应力方向固定不变条件下的单调剪切试验进行了对比分析。试验研究表明,当饱和砂土试样具有水平沉积面时,初始固结主应力方向与剪切方向的不同组合,导致单调剪切过程中总的主应力方向的不断变化,从而显著地影响着饱和砂土不排水单调剪切特性。总的主应力方向是影响饱和砂土不排水单调剪切特性的最根本原因。 相似文献
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土石坝内部存在较多的接触面,在静、动力荷载作用下,接触面的力学特性对坝体的稳定性具有显著的影响。基于动态单剪仪,开展了粗粒料与掺砾粘土接触面循环单剪试验。试验结果表明,初始剪应力加载方向对相对位移有较大影响:相对位移总是在沿初始剪应力加载方向一侧较大;在一个剪切循环内,正、反向加载时,若剪应力较小,发生剪缩变形,若剪应力较大,则发生剪胀变形;卸载时试样发生剪缩变形;整个剪切循环过程中,试样总体上处于剪缩状态;循环单剪过程中,接触面抗剪强度提高;接触面抗剪强度随着法向应力的增大而增大,呈线性关系。 相似文献
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建筑物和构筑物地基土体的主应力方向往往发生旋转,因此研究初始主应力方向角对黄土动变形特性的影响规律具有一定的现实意义。通过对不同初始应力状态下原状与重塑黄土进行动扭剪三轴试验,研究了初始主应力方向角对黄土动变形特性的影响规律,结果表明:在不同初始主应力方向角下,原状黄土抵抗剪切变形的能力大于重塑黄土;在其他条件相同的情况下,初始主应力方向角越大,黄土抵抗剪切变形的能力越弱;随着初始主应力方向角的增大,黄土的动剪切模量随动剪应变变化的规律呈现出减小的变化趋势,而阻尼比则呈现出增大的变化趋势;初始动剪切模量与最大动剪应力随初始主应力方向角的增大而减小。建议在初始平均主应力较大的情况下,考虑初始主应力方向角对黄土动变形特性的影响,试验成果可为黄土地区工程设计提供一定的参考。 相似文献
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地基土单元体在地震荷载作用下将产生主应力轴连续旋转,不同的应力耦合模式对土的强度、孔压以及变形等特性影响显著。利用GCTS空心圆柱扭剪仪,对天津滨海软土场地饱和黏性土进行K0固结下的不同应力耦合模式的循环剪切试验。着重对比相同应力路径下竖向和扭剪双向耦合加载模式,内外围压和扭剪的三向耦合加载模式以内外围压、竖向和扭剪的四向耦合加载模式条件下饱和黏性土的变形特性、循环软化特性。试验结果表明:在相同的动强度下,四向耦合应力模式更容易破坏且变形特性以及软化特性较双向、三向耦合下发展更加迅速;剪应力分量对试样软化变形特性的影响更加显著。 相似文献
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循环荷载作用下饱和砂土的孔压增长规律是土动力学的核心内容之一。基于笔者在给定相对密度、均等固结条件下饱和南京细砂的不排水等幅循环三轴试验结果建立的孔压增量模型,进一步进行了不同相对密度、不同固结比条件下饱和南京细砂的不排水等幅循环三轴试验,将上述均等固结的孔压增量模型拓展为适用于不同相对密度、均等和非均等固结条件的孔压增量模型。采用拓展后的孔压增量模型对试验结果进行分析的结果表明:通过该孔压增量模型预测验证试验的孔压与验证试验测试的孔压具有较好的一致性,说明该孔压增量模型具有普适性。 相似文献
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The mechanical response to cyclic loading of saturated cohesionless soils is usually investigated by means of effective stress method considering pore water pressure changes that lead to reduced strength and stiffness. On the other hand, the behavior of partially saturated sands is different from the behavior of saturated sand deposits. The development of negative pore water pressures in particular makes it difficult to estimate the behavior of partially saturated sands. The response of partially saturated sands, however, can be examined in a physically understandable manner by investigating their energy characteristics independently of pore pressure behavior. To establish a general framework for understanding the behavior of partially saturated sand, a total of 52 resonant column and dynamic torsional shear tests were conducted under undrained conditions. The effects of factors such as the amplitude of shear strain, relative density, saturation ratio and confining pressure on the dynamic characteristics of the sand and on energy dissipation were studied. The use of the energy concept in the evaluation of partially saturated soils is shown to be a promising method for the evaluation of the cyclic behavior of partially saturated sands. 相似文献
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Masayuki Hyodo Noritaka Aramaki Masayuki Itoh Adrian F.L. Hyde 《Soil Dynamics and Earthquake Engineering》1996,15(5):331-336
Cyclic triaxial tests have been carried out on a skeletal carbonate sand from the west coast of Eire. Results are presented for undrained cyclic shear tests on samples with 80% of relative density consolidated under both isotropic and anisotropic conditions. Failure was defined as a 5% double amplitude cyclic strain and a 5% peak axial strain for stress-reversal and non-reversal stress conditions, respectively. Using this definition the cyclic strength for isotropically consolidated samples was affected by the confining pressure although the angular platey nature of the sand resulted in higher cyclic strengths than for a comparable silica sand. For anisotropically consolidated samples the cyclic strength increased with increasing initial static shear stress while on the other hand the cyclic strength normalised in the usual way with respect to the initial confining pressure decreased as this pressure increased. 相似文献
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In the first part of this study, a series of stress-controlled hollow cylinder cyclic torsional triaxial shear tests were conducted on loose to medium dense saturated samples of clean Toyoura sand to investigate its liquefaction behavior. A uniform cyclic sinusoidal loading at a 0.1 Hz frequency was applied to air-pluviated samples where confining pressure and relative density was varied. Cyclic shear stress–strain changes, the number of cycles to reach liquefaction and pore pressure variations were recorded. Results indicate that the liquefaction resistances of uniform sands are significantly affected by the method of sample preparation and initial conditions. 相似文献
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Chen Guoxing Zhou Enquan Wang Zhihua Wang Binghui Li Xiaojun 《Bulletin of Earthquake Engineering》2016,14(8):2185-2212
Liquefaction of saturated loose sand is a major cause of extensive damage to buildings and infrastructures during large earthquakes. A better understanding of the behaviour of liquefied soil is becoming increasingly necessary to mitigate earthquake damage, and the fluid method has become an increasingly popular means to study the behaviour of liquefied soils. The purpose of this study is to determine the fluid characteristics of liquefied fine sand. In this paper, the apparent viscosity was measured as an index of fluid characteristics using the shaking table tests of pre-liquefaction behaviour of saturated fine sand at approximately 45 % relative density; the relationship of apparent viscosity and shear strain rate on liquefying fine sand was indicated as a power-law shear-thinning non-Newtonian fluid; and liquefying fine sand has the alternating behaviour of shear dilatancy and compressibility during cyclic loading. Additionally, a series of a monotonic axial compression loading tests in an undrained manner were performed to measure the shear stress and excess pore pressure ratio relationship on the post-liquefaction saturated fine sand at approximately 50 % relative density. The fluid characteristics of post-liquefaction fine sand exhibits rate dependence and can be described by a combined fluid model of time-independent and time-dependent power-law functions; the time-independent viscous resistance is not relevant to the excess pore pressure ratio; but the time-dependent frictional resistance is closely related to the excess pore pressure ratio. Furthermore, the results of the verification tests demonstrate that the proposed fluid model has good applicability for the fluid behaviour of the post-liquefaction fine sand. 相似文献
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In this study, cyclic hollow cylinder torsional tests were conducted on the reconstituted specimens of Toyoura sand in a practical range of initial density and stress states. The results were employed to evaluate the liquefaction resistance and residual pore water pressure of sand using the strain energy concept. A simple pore water pressure (PWP) model with two calibration parameters was developed for the prediction of residual pore pressure as a function of cumulative strain energy density and the capacity energy of sand. Capacity energy is defined as the cumulative strain energy that is required for liquefaction onset. Based on the results of the tests, an equation is then presented for the estimation of capacity energy in terms of relative density and initial effective confining pressure of sand. This equation is shown to work well as a state boundary curve, which can discriminate between the liquefied and non-liquefied field case histories. Several extra tests were also performed to investigate the effect of initial static shear stress on the proposed PWP model and capacity energy. The results show that initial shear stress has a minor effect on the trend of the proposed PWP model; however, it definitely affects the capacity energy. The final part of the paper aims to confirm reasonable performance of the proposed PWP model by the available observations of seismically induced pore water pressure in shaking table, centrifuge, and real site conditions. 相似文献