场地土液化引起的地下管道上浮反应研究

本文利用虚功原理,建立了场地土液化引起的地下管道的上浮反应分析模型,用弹性地基梁来模拟地下管道,并考虑了土的非线性约束作用、管道的初始变形、液化区长度、管道的初始轴力等的影响。采用非线性增量有限元法,对场地土液化引起的地下管道的上浮反应进行了研究,给出了部分计算结果。     

液化场地土中埋设管线的上浮反应分析

本文利用虚功原理,建立了液化场地土中埋设管线的上浮反应分析模型,考虑到土的非线性约束作用和管道的初始轴力的影响,采用非线性增量有限元法,分析了液化场地土中埋设管线的上浮反应,并给出了部分计算结果。     

液化场地下埋地管道上浮反应影响因素分析

液化场地下埋地管道上浮反应是管道破坏的主要原因,避免因上浮造成的管道破坏,是城市地下生命线工程建设中急需解决的问题。利用ADINA有限元分析软件,建立了液化场地下埋地管道上浮反应的管土接触-土弹簧分析模型。考虑了非液化区的管土接触作用和液化土的非线性约束作用,对埋地管道的上浮位移及轴向应力进行了分析,探讨了管道自身以及液化土的一些参数对埋地管道上浮反应的影响。结果表明:管径、液化土密度,液化区长度越大,埋深、壁厚越小,管道的变形越大,破坏越严重,并给出了几点工程建议。     

液化土中输流管道的竖向地震响应研究

砂土液化是埋地管道遭受地震破坏的主要原因之一。液化土对管道产生上浮力,使管道发生上浮反应,它是随地震发生时间而变化的动态过程。将地震载荷作用下的液化区埋土管道模拟成两端弹性支承的直梁模型,考虑管-土间的相互作用和管内流体与管道之间的流固耦合作用,采用模态叠加法对液化区埋地管道进行地震响应的动态分析,探讨了管道和液化土参数对管道动态上浮反应的影响。通过数值仿真得到了管内流体的流速、流体压力、流体密度、管截面轴向力,管道黏弹系数、液化土容重和相对弹簧系数、地震加速度幅值等因素对管道上浮位移的影响情况。     

粉粒含量对粉土场地液化后变形影响的试验研究

利用全自动多功能三轴仪进行了粉土场地的液化后变形试验,探讨了粉粒含量对液化后应力应变关系的影响.试验时施加动加载使试样达到设定的液化程度,然后立即施加单调荷载,以模拟地震现场发生强震时初始液化到液化后变形的整个过程.研究发现,不同粉粒含量粉土场地发生液化后变形得到的液化后应力应变关系可采用推导的同一理论关系式表示,其系数的差异表明了粉粒含量对粉土液化后变形的影响.验证结果表明该关系式能较好地模拟粉粒含量对粉土场地液化后应力-应变的影响,为同一地区或相似地区粉粒含量变化的粉土场地液化评估提供依据.     

液化微倾场地群桩-土动力相互作用p-y曲线特性

基于OpenSees计算软件建立液化微倾场地群桩-土动力相互作用有限元模型,分析液化微倾场地饱和砂土p-y曲线特性,系统研究了场地倾斜角度、桩径、地震作用幅值和基桩位置对饱和砂土动力p-y曲线特性影响。研究表明:土体即将液化时,桩基土反力达到峰值;土体液化后,土体表现出了流体特性;土反力峰值、桩土相对位移峰值和初始刚度随场地倾斜角度增加而增大;桩径越大,液化砂土的耗能效应越明显;随着地震作用幅值的增加,桩土相对位移峰值和土反力峰值也随之增加;液化微倾场地上坡桩受到的土体侧向流动力大于下坡桩。     

黏粒含量对粉土液化后特性影响的试验研究

设计了分析粉土液化后单调荷载下剪切强度的三轴试验。对粉土施加动荷载使其发生液化后,在不排水条件下施加单调静荷载,直至土体达到强度稳定停止试验。试验结果表明,不同初始有效固结压力、初始孔隙比对液化后土体不排水剪切强度影响较大;液化后粉土表现出明显的剪胀特性,颗粒结构重组,孔压在不排水条件下逐渐消散,土体强度则逐渐增加并最终趋于某一稳定值;剪切强度与初始有效固结压力呈线性关系;孔隙比越小,其液化后剪切强度越大。     

砾性土抗液化能力与其液化判别方法研究进展

从砾性土的定义出发,回顾了砾性土从被认为不会液化到其液化现象引起工程师关注的研究历程及国内外研究进展。总结了含砾量、相对密度等因素对砾性土抗液化能力影响关系的研究现状。介绍了国际上对砾性土场地液化判别的研究成果及各种主流方法的优势与不足;分析了剪切波速方法应用于砾性土场地液化判别的可行性。研究认为:砾性土的液化现象正逐渐被科学界及工程界接受;含砾量对砾性土抗液化能力的影响研究仍然存在较大矛盾,相对密度等影响砂土抗液化能力的因素同样影响砾性土抗液化能力;砂土场地应用的标准贯入、静力触探等液化判别方法不适用于砾性土场地,国际上发展了基于动力触探和贝克尔贯入试验的液化判别方法;剪切波速判别方法在砾性土场地的液化判别中具有优势和潜力,是今后研究的方向之一。     

黏粒含量对粉土液化后特性影响的试验研究

利用多功能动三轴仪的先进功能,对3%、6%、8%、9%、12%和15%黏粒含量的粉土进行了动三轴试验。试样在初始液化后继续施加动荷载,达到不同的双幅轴向应变后施加不排水单调荷载模拟液化后大变形。研究结果表明,相同循环周数时不同黏粒含量对动加载阶段的动剪应力影响规律与其对液化后初始阶段大应变规律有内在联系,即黏粒含量为8%时动剪应力最小而液化后低强度段应变最大,而强度恢复段模量也最低。试验验证结果表明,拟合关系式能较好地反映不同黏粒含量粉土液化后大变形。     

基于累积耗损能量的饱和粉土液化特性试验研究

饱和粉土场地在强地震作用下易发生液化现象。开展饱和粉土的循环三轴试验,以循环加载的累积耗损能量为指标,探讨黏粒含量、密实度、有效围压和循环应力比等因素对粉土液化特性的影响,试验结果表明:粉土液化所需的耗损能量随黏粒含量的增加呈先减小后增大的趋势,当黏粒含量约为8%时粉土的液化耗损能量最低;液化耗损能量随粉土密实程度的增大而逐渐增加,并随初始有效围压的增长而增加,但粉土的液化耗损能量与循环应力比之间的关系不明显。     

液化区埋地管线的数值模拟分析

利用ANSYS有限元分析软件,建立了由场地土液化引起的地下管道上浮反应的分析模型。用土弹簧模型模拟地下管道的受力特点,考虑了管土之间相互作用的非线性特征,通过算例分析了管道在发生上浮反应时的应力应变曲线,探讨了液化区埋地管道在发生上浮位移时的受力特征,得出了一些有意义的结果。主要有:管线的应力应变以轴向为主,并且管顶和管底的受力最大,管侧相对于管顶和管底轴向应力应变很小可以忽略;最大应变位于液化区和非液化区交界处;管线中点处等效应力达到极值等等。     

Distribution and characteristics of gravelly soil liquefaction in the Wenchuan M_s 8.0 earthquake

In this paper,a distribution map of gravelly soil liquefaction that was caused by the Wenchuan M_s 8.0 earthquake in China is proposed based on a detailed field investigation and an analysis of geological soil profiles. The geological background of the earthquake disaster region is summarized by compiling geological cross sections and borehole logs. Meanwhile,four typical liquefied sites were selected to conduct sample drillings,dynamic penetration tests (DPT),and shear wave velocity tests,to understand the features of liquefied gravelly soil. One hundred and eighteen (118) liquefied sites were investigated shortly after the earthquake. The field investigation showed:(1) sandboils and waterspouts occurred extensively,involving thousands of miles of farmland,120 villages,eight schools and five factories,which caused damage to some rural houses,schools,manufacturing facilities and wells,etc.; (2) the Chengdu plain is covered by a gravelly soil layer with a thickness of 0 m to 541 m according to the geological cross sections; (3) there were 80 gravelly soil liquefied sites in the Chengdu plain,shaped as five belt areas that varied from 20 km to 40 km in length,and about ten gravelly soil liquefied sites distributed within Mianyang area; and (4) the grain sizes of the sampled soil were relative larger than the ejected soil on the ground,thus the type of liquefied soil cannot be determined by the ejected soil. The gravelly soil liquefied sites are helpful in enriching the global database of gravelly soil liquefaction and developing a corresponding evaluation method in further research efforts.     

Distribution and characteristics of gravelly soil liquefaction in the Wenchuan <Emphasis Type="Italic">M</Emphasis><Subscript>s</Subscript> 8.0 earthquake

In this paper,a distribution map of gravelly soil liquefaction that was caused by the Wenchuan M_s 8.0 earthquake in China is proposed based on a detailed field investigation and an analysis of geological soil profiles. The geological background of the earthquake disaster region is summarized by compiling geological cross sections and borehole logs. Meanwhile,four typical liquefied sites were selected to conduct sample drillings,dynamic penetration tests (DPT),and shear wave velocity tests,to understand the features of liquefied gravelly soil. One hundred and eighteen (118) liquefied sites were investigated shortly after the earthquake. The field investigation showed:(1) sandboils and waterspouts occurred extensively,involving thousands of miles of farmland,120 villages,eight schools and five factories,which caused damage to some rural houses,schools,manufacturing facilities and wells,etc.; (2) the Chengdu plain is covered by a gravelly soil layer with a thickness of 0 m to 541 m according to the geological cross sections; (3) there were 80 gravelly soil liquefied sites in the Chengdu plain,shaped as five belt areas that varied from 20 km to 40 km in length,and about ten gravelly soil liquefied sites distributed within Mianyang area; and (4) the grain sizes of the sampled soil were relative larger than the ejected soil on the ground,thus the type of liquefied soil cannot be determined by the ejected soil. The gravelly soil liquefied sites are helpful in enriching the global database of gravelly soil liquefaction and developing a corresponding evaluation method in further research efforts.     

液化土中桩基础动力反应试验研究

本文设计完成了包括三种密度饱和砂土和非液化干砂的多工况桩-土相互作用振动台动力试验,研究液化对土体和桩-承台动力反应的影响。通过试验和分析,得到了液化和非液化土层中土体水平加速度、侧向位移和桩-承台的水平加速度、侧向位移、桩身弯矩等指标的反应过程和模式,对比了液化和非液化条件对这些指标的影响方式,提出了各因素影响大小的分析结果。     

Experimental p-y curves for liquefied soils from centrifuge tests

The present study aims to obtain p-y curves(Winkler spring properties for lateral pile-soil interaction) for liquefied soil from 12 comprehensive centrifuge test cases where pile groups were embedded in liquefiable soil. The p-y curve for fully liquefied soil is back-calculated from the dynamic centrifuge test data using a numerical procedure from the recorded soil response and strain records from the instrumented pile. The p-y curves were obtained for two ground conditions:(a) lateral spreading of liquefied soil, and(b) liquefied soil in level ground. These ground conditions are simulated in the model by having collapsing and non-collapsing intermittent boundaries, which are modelled as quay walls. The p-y curves back-calculated from the centrifuge tests are compared with representative reduced API p-y curves for liquefied soils(known as p-multiplier). The response of p-y curves at full liquefaction is presented and critical observations of lateral pile-soil interaction are discussed. Based on the results of these model tests, guidance for the construction of p-y curves for use in engineering practice is also provided.     

桩-液化土相互作用p-y关系分析

基于多工况的桩-液化土体动力相互作用振动台试验,研究地震荷载作用下液化土层中桩土间侧向相互作用力p与桩身和土体间侧向相对位移y之间的关系。将试验得到的实际p-y曲线与采用拟静力法和以API规范为基础的折减系数法计算出的p-y曲线进行对比,结果表明:(1)液化土层中试验得到的桩真实p-y响应及由拟静力法和折减系数法得到的结果都呈非线性变化,三者极限状态有接近一致的趋势,但变化过程差异明显;(2)采用拟静力法和折减系数法都会使液化土层桩基础侧向反力迅速增长,很快达到屈服极限,远远超过实际情况,会导致相当保守的结果;(3)液化进程中控制桩p-y响应的是土体位移而非惯性力,因而拟静力法和折减系数法的原理不适合桩-液化土体动力相互作用分析,不能用于液化土层中桩基础地震响应的计算。     

Seismic base-isolation mechanism in liquefied sand in terms of energy

Seismic base isolation effect in a liquefied sand layer was investigated based on soil properties measured in a series of undrained cyclic triaxial tests. Transmission of seismic wave in a soil model consisting of a liquefied surface layer and an underlying nonliquefied layer was analyzed in terms of energy, considering liquefaction-induced changes in S-wave velocity and internal damping. It was found that, between two different base-isolation mechanisms, a drastic increase in wave attenuation in the liquefied layer due to shortening wave length gives a greater impact on the base isolation with increasing thickness of the liquefied layer than the change of seismic impedance between the liquefied and nonliquefied layer. Also indicated was that cyclic mobility behavior in dilative clean sand tends to decrease the seismic isolation effect to a certain extent.     

Flow Characteristics of Large-Scale Liquefaction-Slip of the Loess Strata in Shibei Tableland, Guyuan City, Induced by the 1920 Haiyuan M8 1/2 Earthquake

Based on the dynamic triaxial liquefaction test of the loess samples which are taken from Shibei tableland, Guyuan City, Ningxia, China, the characteristics of dynamic strain, dynamic stress and pore water pressure are studied under cyclic loading. Triaxial shear test is conducted immediately after the sample reaches liquefaction point. During the test, the property of the liquefied soil is analyzed through fluid mechanics method, whereby the fluidity of the liquefied soil is represented by apparent viscosity.The results show that the fluidity of liquefied loess changes from "shear thickening" to "shear thinning" as the shear force continues, and the fluidity of liquefied loess is closely related to its structure. In addition, in the process of forming a new stable state, the apparent viscosity and deviant stress change with axial strain in a similar approach. When the sample reaches its stable state, it meanwhile shows a relatively stable apparent viscosity. According to the fluid mechanics and the law of conservation of energy, the slip distance of the liquefied soil is estimated, and the results are in good agreement with the field investigation results.