长沙地区典型砂卵石土动力参数计算模型研究

为研究长沙地区典型砂卵石土动力参数计算模型,基于大型动三轴试验,研究了围压、固结应力比及振动频率对砂卵石土动应力—动应变关系的影响,结合动参数模型及试验数据拟合出砂卵石土动弹性模量及阻尼比的经验公式,研究结果表明:围压对砂卵石土动本构关系影响显著;固结应力比大于1.0时,初始剪应力存在对砂卵石土的动强度增加不利;振动频率试验数据表现出良好的归一性,对砂卵石土动本构关系影响小;砂卵石土动力参数经验公式具有良好的可靠性。     

武汉砂土动剪切模量与阻尼比的试验研究

以武汉地铁4号线二期工程越江段饱和砂土为研究对象,通过室内GDS动力三轴试验,较为系统地研究了在单向循环荷载作用下砂土的动剪切模量和阻尼比规律特性及其影响因素。试验结果表明:动剪切模量、阻尼比与动剪应变的关系可以用Hardin-Drnevich双曲线模型进行描述;动剪切模量随动应变的增大而减小,随围压和固结比的增大而增大,而阻尼比的变化规律与动剪切模量相反。从而为工程建筑物的抗震设计提供了重要依据。     

饱和黄土静、动力特性试验研究

对重塑饱和黄土进行静、动力三轴试验,探讨了饱和黄土的静、动力特性。根据静力试验结果分析了饱和黄土静强度的变化规律,建立了饱和黄土的双曲线模型,并推导出其邓肯-张模型参数供本地区工程建设及数值分析参考使用。根据饱和黄土振动三轴试验结果,给出了其在等压固结与非等压固结条件下的动强度变化规律。在对饱和黄土动强度分析的基础上对其进行归一化处理后,建立了饱和黄土静、动强度相关性的经验公式,利用该公式可以实现采用饱和黄土的静力强度参数推求其动强度,从而达到减少场地动力稳定性分析中试验工作量的目的。     

饱和砂土地基中群桩侧向动力响应试验与数值模拟对比研究

可液化场地中桩基尤其是群桩的横向动力响应特性的研究,一直是国内外岩土地震工程领域关注的热点问题。由于桩-土-承台结构动力相互作用过程的复杂性,基于砂土-群桩-承台结构模型振动台试验,对饱和砂土中群桩侧向动力响应特性进行了分析。在此基础上,通过大型有限元软件OpenSees建立了三维模型,展开了数值模拟研究,并将数值模拟结果与试验结果进行了对比研究。结果表明:在正弦波输入下,无论是干砂还是饱和砂土试验,群桩承台加速度和位移时程与模拟承台加速度和位移时程在曲线趋势和峰值上基本吻合;在El-Centro地震波输入下,干砂和饱和砂土的模拟承台加速度时程曲线峰值和趋势与试验的比较吻合,而承台位移时程曲线频率比试验要高,但承台位移峰值基本一致。     

砂卵(砾)石动剪切模量比与阻尼比的试验研究

砂卵(砾)石的动剪切模量比和阻尼比是河谷地貌场地地震反应分析的重要参数,对设计地震动参数的确定有重要影响。本文利用商洛市地震小区划项目砂卵石的动三轴试验结果,结合其他砂卵(砾)石动三轴试验结果,分组统计得到了稍密、中密、密实砂卵(砾)动三轴试验的推荐结果。建立了典型场地模型,研究了其动剪切模量比和阻尼比的不确定性对场地地震反应的影响。研究表明:动剪切模量比、阻尼比平均值±1倍标准差的不确定性对砂卵石场地峰值加速度的影响较小,说明了分组及统计结果的合理性;不同概率水平下,动剪模量比、阻尼比的变化导致高频部分反应谱有明显差异,0.04-0.1s的反应谱变化范围在20%左右,但对大于1.0s的长周期反应谱影响很小。针对砂卵(砾)石动剪切模量比和阻尼比的研究对提高工程场地设计地震动参数的可靠性具有重要意义。     

地震荷载下饱和砂土孔压增长时程计算方法

本文采用逐波累计方法,依据适于不同固结条件的孔压增量模型,计算每一应力循环的孔压变化,可给出非均等固结复杂情况下孔压实时增长过程。采用不同固结比两种砂进行若干典型地震荷载动三轴液化试验,试验结果与所提方法的计算结果有良好对应关系,表明本文方法可有效地描述地震荷载作用下非均等固结饱和砂土孔压增长过程。     

粉煤灰改良饱和黄土动力特性研究

以资源循环再利用与提高饱和黄土地基抗震性能为目的,通过对不同掺量粉煤灰改良饱和黄土进行动弹性模量-阻尼比试验,研究了动荷载作用下粉煤灰掺量对饱和改良黄土动骨干曲线的影响,同时对不同掺量粉煤灰改良饱和黄土初始动弹性模量、最大动应力幅值、动弹性模量与阻尼比进行了对比研究。研究结果表明:饱和压实素土与不同掺量粉煤灰改良饱和黄土动骨干曲线均可用双曲线模型进行描述,模型参数受粉煤灰掺量影响较大;粉煤灰的掺入可有效改善饱和黄土地基抗震性能,随粉煤灰掺量增加,不同掺量饱和改良黄土动弹性模量与阻尼比分别总体呈增大与减小趋势;考虑粉煤灰改良饱和黄土抗震性能与经济成本,提出了饱和改良黄土最佳粉煤灰掺量为20%~25%;并基于回归分析,给出了饱和改良黄土动弹性模量衰减经验公式与阻尼比增长经验公式及其拟合参数。     

饱和珊瑚砂液化特性动三轴试验研究

为调查饱和珊瑚砂液化相关特性与发展规律,针对饱和Chibishi珊瑚砂,开展一系列不排水循环三轴试验,研究相对密度D_r和循环应力比CSR对饱和Chibishi珊瑚砂的超孔隙水压力Δu、轴向应变ε_a及动强度特性的影响,并分析不同地区珊瑚砂抗液化强度的差异性。结果表明,饱和Chibishi珊瑚砂的Δu发展模式根据不同的CSR水平可以分为前期均匀增长型、前期突增型和后期突增型;此外,采用一种新的孔压模型对前期均匀增长型、前期突增型的孔压比r_u进行表征,Chibishi珊瑚砂在相同的D_r条件下,双幅应变ε_DA达到5%的循环次数N随着CSR水平的增加而逐渐减小;各珊瑚砂在同一里氏震级对应的等效循环振动次数下,抗液化强度CRR的增长模式存在显著差异。研究结果可丰富对珊瑚砂液化特征的认知,同时对近岸和沿海工程的抗震设计提供参考依据。     

不同混合比橡胶砂动力性能试验研究

橡胶材料具有廉价、阻尼大、弹性变形较好等优点,将废旧轮胎颗粒加入路基填料中可在减少环境污染的同时提高路基抗震性能。本文通过橡胶砂基本物性试验和动三轴试验研究了不同混合比橡胶砂的减震性能,分析对比了不同混合比橡胶砂和纯砂的动弹性模量、阻尼比、动强度、内摩擦角及动应力－应变滞回曲线的变化规律。得出结论:橡胶砂动弹性模量受动应变影响较大,当动应变较大时橡胶砂的弹性模量大于纯砂;掺入橡胶颗粒可提高纯砂的阻尼比和动强度;实际工程应用中需要考虑橡胶砂混合比的影响。     

循环荷载作用下钙质砂液化及体变特性

钙质砂是岛礁建设的重要材料之一,具有颗粒形状不规则与易破碎特性,钙质砂在动荷载下性质与石英砂有所区别,对钙质砂的液化特性及体变规律进行探究,能够更好地揭示钙质砂液化沉降规律。采用动三轴试验对饱和钙质砂进行了一系列不排水循环剪切试验。孔隙水压力的上升速率会影响钙质砂的抗液化性,实验结果表明：钙质砂孔隙水压力的上升速率受密实度、有效围压等因素影响。在动荷载作用下,试样上下孔隙水压力存在少量差值,同一试样上下孔隙水压力差受试样密实度、围压以及循环应力比影响。钙质砂在循环荷载作用下体变的主要影响因素是密实度,密实度越大,体变率也会越小,级配和围压对体变率的影响较小,且体变率较石英砂更低。     

饱和南京细砂孔压增量模型的普适性研究

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。     

含微生物气泡高饱和砂土循环三轴剪切CFD-DEM模拟

为探究砂土液化的微观机理,根据室内试验中微生物反硝化反应气泡的生成速率,建立数值模拟的时效性关系,分别制取微生物处理0天、2天、3天和5天的高饱和砂土试样,采用CFD-DEM耦合方法模拟不同工况下砂土试样的循环三轴不排水剪切试验。依据砂土试样的力链分布、抗液化振次、孔压比、轴向应变和力学配位数在加载过程中的变化情况,从宏微观角度分析砂土试样的抗液化能力。模拟结果表明:含微生物气泡高饱和砂土的抗液化强度较饱和砂土有所提升;随着微生物处理时间的增加,砂土试样的饱和度降低,孔压比和轴向应变的累积变慢,抗液化能力增强。     

分层液化土中桩基侧向动力反应机理的试验研究

饱和砂土中的桩基侧向动力响应研究一直是岩土工程界与地震工程领域关注的热点,尤其是群桩侧向动力响应机制是需要重点研究的课题之一。基于振动台试验,通过输入2种不同的波形,采用FBG光栅传感系统对饱和砂土中的单桩与群桩侧向动力响应特性和典型测试点的桩土动力p—y滞洄曲线进行研究。研究结果表明：振动初期,单桩和群桩试验孔压增长不大,随后单桩孔压迅速上升,振动后期逐渐下降至0.5,而群桩孔压则上升缓慢;单桩试验土表加速度在振动初期逐步升高后又迅速降低,且加速度放大值略大于台面加速度值,群桩试验土表加速度在振动初期逐渐升高时就达到了最大,且随着孔压比的升高,加速度没有继续放大,而是逐渐减小,直到后期与单桩试验土表加速度重合;饱和砂土液化对单桩承台加速度和位移的影响较大,群桩承台侧向动力响应对液化的敏感程度略低于单桩承台;在振动输入和承台输入相同的条件下,液化后的群桩基础比单桩基础能更好地抵抗侧向力的作用。     

饱和砂土地铁车站的振动台试验研究

地震作用下,饱和砂土地层地铁车站的动力反应特征是城市轨道工程抗震的关键问题。以太原地铁新近沉积粉细砂地层地铁工程为对象,通过模拟地震运动输入的饱和砂土地基地下结构的振动台模型试验,分析了不同峰值加速度地震作用下饱和砂土与地下结构相互作用的动力反应性状。研究了地震波作用的放大效应与频率特征,动孔压比增长发展过程和液化区域分布,以及动土压力的变化规律。表明加速度放大系数为1.5~2.0;0.1~0.25g峰值加速度地震作用下饱和砂土均产生动孔隙水压力累计发展;0.3g峰值加速度地震作用下饱和砂土产生液化,抑制了土与地下结构的振动放大效应,地表面大量冒水,结构模型出现了明显上浮,地下结构两侧产生震陷。     

Energy approach to unsaturated cyclic strength of sand

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.     

Flow deformation of liquefied sand under constant shear load and its application to analysis of flow slide of infinite slope

This paper intended to evaluate the behavior of saturated sand and sloped ground subjected to flow failure with seepage of pore water in the ground after earthquake and the resultant liquefaction. Triaxial compression tests of sand with constant deviator stress but changing of pore pressure and volume of the specimens were conducted in this study. It was revealed that the relation between the volume change and the amount of shear strain during deformation depended on the initial density of the sand but it did not much depend on shear stress and initial confining stress levels. Based on this test results and numerical analysis of the seepage of pore water in liquefied ground, a methodology was proposed to predict the deformation of inclined ground due to liquefaction.     

Experimental investigation on fluid characteristics of medium dense saturated fine sand in pre- and post-liquefaction

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.     

Seismic response of adjacent dense and loose saturated sand columns

Compaction or densification of loose saturated soils has been the most popular method of reducing earthquake related liquefaction potential. Such compaction of a foundation soil is only economical when limited in extent, leading to a case of an ‘island’ of improved ground (surrounded by unimproved ground). The behavior of the densified sand surrounded by liquefied loose sand during and following earthquakes is of great importance in order to design the compacted area rationally and optimize both safety and economy. This problem is studied herein by means of dynamic centrifuge model tests. The results of three heavily-instrumented dynamic centrifuge tests on saturated models of side-by-side loose and dense sand profiles are discussed. The test results suggest the following concerns as relates to ‘islands’ of densified soil: (1) there is a potential strength degradation in the densified zone as a result of pore pressure increase due to migration of pore fluid into the island from the adjacent loose liquefied ground; (2) there is a potential for lateral deformation (sliding) within the densified island as the surrounding loose soil liquefies.     

砂土自由场地震响应的离心机试验研究

离心机模型试验是研究岩土地震工程问题的有效手段。本文使用层状剪切箱,通过干落法制备了均匀的砂土模型,进行了离心机振动试验;观测了振动过程中孔隙水压力的发展,土体的加速度响应、侧向变形以及竖向沉降。结果表明,土体的运动和变形与孔隙水压力的发展密切相关,但离心机中的试验现象和现场观测的现象存在显著区别。研究结果增强了对振动过程中土-水之间相互作用机理的理解,同时为自由场地震响应分析方法的验证提供了基础数据。     

黄河三角洲粉土液化的试验研究

在野外自然地理和地质调查的基础上，以黄河地区可液化场地粉土为研究对象，利用室内动三轴和振动柱试验进行测定，分析了动荷载作用下粉土的动应力应变关系并模拟了地震荷载作用下粉土的孔压响应及抗液化强度，得出了液化破坏标准，提出了原状粉土的振动孔压上升模型。对试验结果进行分析发现，随着粘粒含量的增加，粉砂、粉土、粉质粘土、粘土达到相同剪应变所需的动剪应力也依次增加；粉土孔压比0．68、粉砂土孔压比0．87作为液化破坏开始的标志；粉土发生液化所需的循环应力比大于砂土。这些研究为以后建立适合本地区的饱和地基土地震破坏判别方法提供了参数和依据。