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为了探究铁矿尾矿砂抗剪强度参数随固结度的变化规律,分别对不同固结度、不同干密度的铁矿尾矿砂进行三轴固结不排水试验(CU试验),以总应力法和有效应力法得到尾矿砂的抗剪强度参数及有效抗剪强度参数。分析表明,对于同一干密度的尾矿砂,随着固结度的增加,抗剪强度指标及有效抗剪强度指标均逐渐增加。固结度的变化对黏聚力c及有效黏聚力c′影响较小,对内摩擦角φ以及有效内摩擦角φ′影响较大。φ及φ′随着干密度的增加成线性增长趋势,且不同固结度下的γd-φ曲线、γd-φ′曲线拟合度较高。因此,在尾矿坝稳定性评价及安全管理中,考虑尾矿砂的抗剪强度随固结度的不同而变化,可使尾矿坝稳定性分析更符合实际情况。 相似文献
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《地震工程与工程振动》2015,(3)
利用基于考虑钢筋和混凝土材料非线性的纤维单元模型及土体动力弹塑性模型的有限元程序Open Sees,建立土-结构二维平面应变有限元模型,对强震作用下国外某核电站取水结构进行弹塑性动力时程分析。研究取水结构以及地基土的地震动力反应特性,并对取水结构的变形性能和承载能力进行评估。结果表明,在设计基准地震作用下,取水结构与周围土体的变形呈现出较大的非线性,土体变形以剪切为主,其值随深度的增加逐渐减小。受土-结构动力相互作用的影响,取水结构周围土体的加速度反应较大。取水结构的最大内力和最大抗剪需求能力比分别发生在下层侧壁与底板相交的角点处和靠近侧壁的底板端部。取水结构的层间位移角和抗剪承载力均满足规范规定的抗震安全性要求,并且具有一定的安全裕度。 相似文献
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编制完全耦合的三维排水有效应力动力反应分析程序,对可液化地基进行三维地震响应分析,探讨了不同土性参数、不同土层构成和不同附加压重等因素对可液化地基抗液化性能的影响。结果表明:在地震荷载作用下,天然饱和砂土地基中的超孔隙水压力随深度的增大而增大;在不同深度处,超孔压峰值到达的时刻比地震加速度峰值到达的时刻要晚;随输入地震加速度的减弱,深层处的超孔压开始消散或基本保持不变,浅层处的超孔压保持不变或略有上升,这一现象与土性参数、输入地震荷载的情况等因素有关;土性参数对土体本身的抗液化性能有重要影响,初始孔隙比越小,相对密度越大,土体的抗液化能力越强;附加压重有利于地基抗液化能力的提高;随着附加压重的增大,超孔压比减小;附加压重对地基中超孔隙水压力的增长有明显的抑制作用。 相似文献
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土颗粒是构成饱和地基的重要基础,因此无论用何种方法分析饱和地基时,均不能忽视土颗粒的物理性质。用传统方法计算时均假设土是均质、各向同性的,不考虑实际土颗粒的粒径和形状,与实际情况不符。本文采用了不同形核点数的不同不规则度的Voronoi网格划分模拟了实际土颗粒的结构,建立有限元模型并进行数值分析。计算结果表明,在不同时刻沿深度的孔压数值、有效应力分布和固结度等方面,采用该Voronoi网格划分的有限元模拟结果和太沙基常规模型的理论解进行对比,计算结果趋于一致,说明Voronoi图在对土体划分时是可行的,并且该模型在进行饱和土体一维固结的相关参数计算时具有很好的精度。 相似文献
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土石坝(超)深厚覆盖层中的深埋细粒土难以完全挖除(换填),其在地震作用下的动力变形特性和强度特性是科研设计人员关注的问题。本文进行某大型土石坝工程超深厚覆盖层地基中的深埋粉砂层土动力特性三轴试验,研究其在地震荷载作用下的动力变形与强度特性,并为大坝—地基系统动力分析和抗震设计提供基础资料。研究表明:试验土料最大动剪模量和平均有效应力在双对数坐标中呈良好的线性关系,不同围压力条件下的模量衰减(阻尼比增长)曲线可以采用参考剪应变的方式进行归一,可用试验确定特定围压力条件下的模量衰减(阻尼比增长)曲线外延推求任意围压力条件下的相应曲线;试验土料在地震荷载作用下的动强度特性主要受土体密度、固结条件和围压力条件等控制,当土体处在不等向固结状态时,不同动力破坏标准下确定的土体动强度特性参数差异较大。 相似文献
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当土体总应力状态保持不变时,基质吸力的提高是导致孔隙水排水、土样体积收缩、孔隙结构改变的根本原因,通过吸力可以将土壤收缩曲线和土水特征曲线联系起来进行比对研究。采用广义有效应力原理分析超固结土样和正常土样的失水过程,结果表明:超固结土样中存在着相应的先期固结压力的吸力值,称之为先期固结吸力ψc。当土样吸力小于ψc时,超固结土样和正常固结土样的收缩曲线、土水特征曲线不同:超固结土孔隙比随吸力提高而减小的坡度较缓,约等于土样的回弹再压缩指数,土样处于结构性收缩阶段;先期固结压力越大,土水特征曲线的进气值越高。当土样吸力高于ψc时,超固结土样和正常固结土样的收缩曲线、土水特征曲线重合。 相似文献
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通过饱和原状黄土常规三轴试验和非饱和原状黄土等吸力三轴试验研究吸力和净围压对非饱和黄土强度变形的影响,并用HUANG等、胡冉等和方祥位等提出的土水特征曲线模型分析剪切过程中排水规律。研究结果表明:等吸力下原状土样固结剪切体积变形随净围压增大而增大;等净围压下原状土样固结剪切体积变形量随吸力的增大基本呈减小趋势。p-q平面内饱和土CSL线逐渐超过低吸力下非饱和土CSL线,原因在于随着p值增大,相对于非饱和土,饱和土孔隙比越来越小,较小孔隙比对抗剪强度的贡献逐渐大于非饱和土吸力对抗剪强度的贡献。应用固结稳定的数据拟合出HUANG等和胡冉等提出的模型参数,并预测剪切过程中的排水量,发现剪切速率对排水量有影响,这两种模型适用于剪切速率慢,排水充分的情况,而方祥位等提出的模型对不同剪切速率会拟合出不同的参数。 相似文献
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Critical state soil mechanics is a useful framework to understand sand behavior. In this paper, a relationship is developed for estimating undrained critical shear strength of sands based on the critical state framework. The relationship is validated by comparison with laboratory test results and sand liquefied strength from field liquefaction failure case histories. Using this relationship, the influence of fines content on undrained critical shear strength is studied for different combinations of effective stress and density. The parametric study indicates that depending on soil void ratio, effective stress, and the shape and mineralogy of the fine particles, undrained critical strength may increase, remain the same, or decrease as the amount of fines content increases. Both the susceptibility to liquefaction and the severity of strain-softening are affected by adding fines. It is suggested that the critical state parameter is inadequate for describing the behavior of liquefiable sands and sand shearing-compressibility should be taken into account in liquefaction analysis. 相似文献
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Estimation of residual shear strength ratios of liquefied soil deposits from shear wave velocity 总被引:1,自引:1,他引:0
Pelinzener 《地震工程与工程振动(英文版)》2012,11(4):461-484
For sites susceptible to liquefaction induced lateral spreading during a probable earthquake, geotechnical engineers often need to know the undrained residual shear strength of the liquefied soil deposit to estimate lateral spreading displacements, and the forces acting on the piles from the liquefied soils in order to perform post liquefaction stability analyses. The most commonly used methods to estimate the undrained residual shear strength (Sur) of liquefied sand deposits are based on the correlations determined from liquefaction induced flow failures with SPT and CPT data. In this study, 44 lateral spread case histories are analyzed and a new relationship based on only lateral spread case histories is recommended, which estimates the residual shear strength ratio of the liquefiable soil layer from normalized shear wave velocity. The new proposed method is also utilized to estimate the residual lateral displacement of an example bridge problem in an area susceptible to lateral spreading in order to provide insight into how the proposed relationship can be used in geotechnical engineering practice. 相似文献
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The coupled mechanics of fluid-filled granular media controls the physics of many Earth systems, for example saturated soils, fault gouge, and landslide shear zones. It is well established that when the pore fluid pressure rises, the shear resistance of fluid-filled granular systems decreases, and, as a result, catastrophic events such as soil liquefaction, earthquakes, and accelerating landslides may be triggered. Alternatively, when the pore pressure drops, the shear resistance of these geosystems increases. Despite the great importance of the coupled mechanics of grain–fluid systems, the basic physics that controls this coupling is far from understood. Fundamental questions that must be addressed include: what are the processes that control pore fluid pressurization and depressurization in response to deformation of the granular skeleton? and how do variations of pore pressure affect the mechanical strength of the grains skeleton? To answer these questions, a formulation for the pore fluid pressure and flow has been developed from mass and momentum conservation, and is coupled with a granular dynamics algorithm that solves the grain dynamics, to form a fully coupled model. The pore fluid formulation reveals that the evolution of pore pressure obeys viscoelastic rheology in response to pore space variations. Under undrained conditions elastic-like behavior dominates and leads to a linear relationship between pore pressure and overall volumetric strain. Viscous-like behavior dominates under well-drained conditions and leads to a linear relationship between pore pressure and volumetric strain rate. Numerical simulations reveal the possibility of liquefaction under drained and initially over-compacted conditions, which were often believed to be resistant to liquefaction. Under such conditions liquefaction occurs during short compactive phases that punctuate the overall dilative trend. In addition, the previously recognized generation of elevated pore pressure under undrained compactive conditions is observed. Simulations also show that during liquefaction events stress chains are detached, the external load becomes completely supported by the pressurized pore fluid, and shear resistance vanishes. 相似文献
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During earthquake events, low-plasticity silt undergoes a reduction in shear strength and stiffness due to development of excess pore pressure induced by cyclic loading. With reconsolidation, during which process excess pore pressure is dissipated, the shear strength and stiffness can be regained. However, due to the low permeability of silts (compared to sands), the dissipation of excess pore pressure and the reconsolidation of low-plasticity silt takes much more time. This paper investigates the postliquefaction shear behavior of Mississippi River Valley (MRV) silt at various degrees of reconsolidation using triaxial tests. Test results indicate that there was a steady increase, in shear strength and stiffness, at both large and small deformations, with increase in the degree of reconsolidation. The postliquefaction silt showed the effect of the apparent OCR, which had a close effect on postcyclic shear behavior as did the OCR on the static behavior. The critical state lines of MRV silt were different for pre- and post-liquefaction conditions. 相似文献
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A series of undrained cyclic triaxial tests were performed on sand–clay mixtures with various sand–clay mixing ratios. Prior to the primary tests, the threshold fines content was examined by consistency tests, which was found to be approximately 20%. For sand–clay mixtures with a sand-matrix (fines content less than the threshold fines content), the cyclic shear strength of low-density mixtures increases and that of high-density mixtures decreases with increasing fines content. However, for sand–clay mixtures with a fines-matrix (fines content greater than the threshold fines content), there exists a unique correlation between the cyclic shear strength and global void ratio for different fines content. The equivalent granular void ratio is introduced in this paper to account for the contribution ratio of the fines to soil skeleton. As a result, a unique relationship between cyclic shear strength and equivalent granular void ratio was observed for pure sand and sand–clay mixtures with a sand-matrix. 相似文献
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采用室内重型击实实验对含砾黏土的压实特性进行分析,结合CT断层扫描研究材料整体干密度、最优含水率及黏土的压实程度与掺砾量、含水率等因素之间的关系。根据无侧限抗压强度实验结果,比较不同掺砾量和不同含水率下的无侧限抗压强度大小。结果表明:掺砾量较低时砾粒与黏土之间就已出现粒间空隙;含水率较高时,这些空隙及黏土孔隙中的水在击实过程中难以排出,同时水还阻碍了封闭气泡的逸出,造成黏土的压实效果明显降低;随着含砾量的增加砾粒逐渐起到骨架作用,减小了作用在黏土上的击实能量,也造成黏土的压实程度差于纯黏土。含砾黏土的无侧限抗压强度主要由黏土成分的密实程度控制,因而受到砾粒含量和含水率的影响,整体上随着含砾量的增加而降低,含水率较高时的下降幅度更明显。 相似文献
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剪切波速与地基土的抗剪强度、剪切模量和卓越周期等参数密切相关,是地震安全性评价中判定场地类别的一个主要指标和参数。鉴于海域工程中剪切波速往往难以直接由原位测得,而室内实验结果又常常与野外现场物探测试值存在较大差异,因此,如何通过其他途径有效获取满足工程需要的剪切波速参数在海域工程的地震安全性评价等方面具有迫切的实用需求。为此本文通过对渤海海域数十个石油平台项目中一系列饱和黏性土样品的剪切波速与抗剪强度实验数据的统计分析,尝试采用多种可能的函数来拟合确定二者之间的经验关系。结果表明:对于渤海海域黏性土剪切波速V_s与抗剪强度S_u之间的最佳统计经验关系为幂函数V_s=53.751S_u~(0.376)。此关系可为渤海海域工程中通过不排水抗剪强度估算剪切波速提供一种简便可行的实用性方法。 相似文献
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为研究压实度对脱硫石膏动强度与动孔压特性影响,对压实度为0.85、0.90和0.95三组脱硫石膏进行等压固结不排水振动三轴试验,试验围压为100 kPa、200 kPa和400 kPa。结果表明:随压实度增大,脱硫石膏颗粒间作用力愈强,颗粒联结骨架越不容易破坏,脱硫石膏动强度越大,动孔压增长越慢;试验压实度范围下,脱硫石膏动剪应力比和动内摩擦角均与压实度呈线性相关;试验用脱硫石膏可分类定名为低液限粉土,其动强度曲线和动孔压发展模式均与常规粉土类似,分别可通过幂函数和对数函数表征,经F值试验法检验,其统计回归显著性水平均为"高度显著"。 相似文献