接触对桩-土-结构动力相互作用体系的影响

为了考察桩-土接触效应对结构地震反应的影响,利用有限元软件ABAQUS建立了土-桩-框架二维有限元模型,分别采用损伤塑性模型和动力粘塑性记忆型嵌套面模型模拟混凝土和土体,利用rebar单元模拟混凝土内的钢筋,取得了较好的计算效果.计算分析中采用19条不同频谱的地震波记录,考虑了地震动强度、桩径、摩擦系数等因素,以层间位移角和桩顶最大位移为主要评价指标,揭示相互作用体系的动力响应特性.分析认为,计算结果对桩、土摩擦系数的取值不敏感;不考虑土-桩接触时,近场土体的动力反应与实际情况存在一定的误差,且上部结构和桩基的动力反应会被低估,应该考虑桩-土动力接触效应;地震动强度增加时,随着结构进入塑性状态,低估程度减小;桩径增加时,低估程度没有显著变化,虽然桩基和上部结构的反应都有所减小.     

框剪结构土-结构相互作用地震反应分析

本文在全面考虑上部结构、基础及下部土体实际情况和受力特性的基础上,开发了一种平面框剪土-结构相互作用的简化分析模型。在这个模型中,利用矩阵位移法的概念,同时考虑框架和剪力墙(筒体)的协同工作原理,将上部结构简化成平面的框架-剪力墙(筒体)结构,这一模型可以很好地模拟常用高层建筑体系的弯曲特性和弯剪特性。地基土采用一块在计算平面内高度为H,宽度为B,而在出平面方向厚度为t的土体作为分析模型,并对MSC.Marc进行了二次开发,将多层土E-B本构关系模型作为子程序嵌入其中,使用E-B本构关系模型来考虑它的非线性特性,利用粘-弹性人工边界作为地基土的边界条件。用接触迭代算法考虑了桩、箱-土之间的相互作用。最后,采用本文的方法对某高层框剪建筑进行了分析,并与不考虑土-结构相互作用的地震反应分析结果进行了对比。通过算例,本文初步探讨了在土-结构相互作用模型中,考虑和不考虑桩-土间相互作用对结构地震反应的影响,并得到了一些结论,证明了本文方法的适用性。     

桩基-非线性框剪结构相互作用体系(下)-- 相互作用对结构地震反应的影响

本文研究桩基-非线性框剪结构相互作用体系的地震反应。其中上部框架和剪力墙结构分别用门型单元和四弹簧墙单元进行分析;桩基阻抗函数通过单桩阻抗和动力相互作用因于求得。采用频-时域混合法求解体系的动力方程,本文研究了在桩基-框剪结构相互作用体系地震反应分析中,桩基阻抗的频率相关性对结构地震反应的影响,并从土体剪切波速和地震波强度两个方面,研究了土-桩-结构相互作用对框剪结构地震反应的影响。     

层状土介质中群桩及其上部结构体系对任意入射地震波的响应

本文舍弃桩基动力分析中的土介平面应变假定，采用薄层内位移纡性变化条件下的动力Ｇｒｅｅｎ函数形成桩－土－桩相互作用所需的土介质柔度矩阵，用梁单元模拟桩的运动，用振型分解方法来考虑上部结构与桩基承台间的动力相互作用，以任意地震波入射为初始运动输入，建立了层状土介质中群桩及其上部结构体系对放射地震波响应的半解析分析模型，研究了桩基及其上部结构体系对不同角度入射、ＳＨ、ＳＶ和Ｐ波的动力响应，结果表明，本文     

大直径扩底灌注桩的地震反应特性

大直径扩底桩的地震反应分析对其抗震设计至关重要。本文采用ABAQUS有限元程序建立地震荷载作用下扩底桩-土-结构和普通等直径桩-土-结构动力相互作用体的三维有限元模型,分析大直径扩底桩与普通等直径桩地震反应的差异。桩周土采用Drucker-Prager弹塑性模型以考虑土体的非线性,桩体采用线弹性模型,桩与桩周土之间设置非线性接触。输入Imperial Vally地震波,对两种桩基的地震反应进行了数值计算,分析了桩土模量比、软夹层、上部质量等因素对桩基地震反应的影响。结果表明:与普通等直径桩相比,扩底桩的抗震性能没有明显提高,扩底直径对抗震性能影响不大,增大扩底桩直径,并不能提高扩底桩的抗震性能;上部结构的质量及桩土模量比对桩基的动力响应影响显著。     

桩-土-结构动力相互作用的线弹性地震反应分析

采用集中质量法(简化模型)，用ANSYS软件作为桩—土—结构动力相互作用分析的工具，建立了小震下钢筋混凝土剪切型结构考虑桩—土—结构动力相互作用效应的计算模型，进行了桩—土—结构相互作用线性体系的模态分析，研究了考虑桩—土—结构相互作用体系的自振特性；进行了小展下桩—土—结构相互作用体系弹性地震反应时程分析，研究了土—结构动力相互作用效应对结构地震反应的影响；得出如下结论；考虑桩—土—结构相互作用效应后，结构体系的自振特性及结构的地震反应将有所改变。     

桩-土相互作用弹簧对倾斜液化场地-群桩-上部结构体系的影响

桩-土-上部结构体系的动力相互作用是一个复杂的过程,尤其是在倾斜液化侧向扩展流动（侧扩流）场地中,由于地震过程中场地产生地面永久大变形,桩土间有可能产生错动滑移与开裂等非线性反应,因此桩-土相互作用模拟至关重要。为了探究桩-土非线性接触对倾斜液化场地-群桩基础-上部结构体系动力响应的影响,本文基于OpenSees分别建立了考虑桩-土相互作用弹簧和桩土结点之间直接绑定的有限元数值模型。结果表明：考虑桩-土相互作用Pyliq弹簧时,土体加速度幅值略微降低,桩基对土体的约束明显变弱,土体残余位移增大。同时,具有Pyliq弹簧的模型能较好地模拟桩的曲率响应,而采用桩土结点直接绑定的模型高估了桩顶曲率,进而无法准确估计桩基抗弯最不利位置。桩-土相互作用弹簧对上部结构动力响应的影响较小。     

地震作用下上部结构刚度改变对基桩受力的影响

结合典型工程实例，采用在土体侧向边界节点处用弹簧并联阻尼器来进行模拟，在平面应变单元和桩体梁单元连接处用约束方程的方法进行节点耦合、满足连续条件，选择桩、土、荷载参数，用整体有限元方法进行桩－土－结构相互作用体系的地震反应分析。重点讨论了三种不同的上部结构刚度对桩基地震内力的影响，得到了在水平地震荷载作用下上部结构刚度的增大将增大桩基的内力及水平位移，且桩顶及桩身处于第一个软硬土层交界面处的截面的内力尤为突出等结论。关键词：上部结构刚度改变；桩－土－结构相互作用；弹性－阻尼边界；地震反应分析     

桩基—非线性框剪结构相互作用体系（下）—相互作用对结构地 …

本文研究桩基－非线性框剪结构相互作用体系的地震反应。其中上部框架和剪力墙结构分别用门型单元和四弹簧墙单元进行分析;桩基阻抗通过单桩阻抗和动力相互作用因子求得。采用频－时域混合法对解体系的动力方程,本文研究了在桩基－框剪结构相互作用体系地震反应分析中,桩基阻抗的频率相关性对结构地震反应的影响,并从土体剪切波速和地震波强度两个方面,研究了土－桩－结构相互作用对框剪结构地震反应的影响。     

爆破地震作用下桩-土-结构相互作用的数值模拟

土-结构动力相互作用是地震工程和结构抗震的重要研究内容,但目前对爆破地震作用下土-结构动力相互作用的研究较少。运用大型有限元软件ANSYS/LS-DYNA,建立了桩-土-结构相互作用体系的三维有限元模型,由桩尖输入实测爆破地震波,取得了良好的计算效果。计算结果表明：考虑桩-土-结构相互作用后,群桩基础中每个桩的位移、加速度和剪应力幅值均呈桩顶大、桩尖小的倒三角分布,桩与承台的接合部比较容易受到损坏;桩-土-结构相互作用体系在爆破地震波冲击后,还会发生几次振动,但是这些振动产生的影响要小于爆破地震产生的影响,这与实测结果相符合;爆破地震波冲击下,群桩基础中,角桩顶部表面的桩土接触压力较大,但在爆破地震波冲击后,中心桩顶部表面的桩土接触压力较大,且具有一定的周期性,直至衰减为零。     

基于OpenSees的桩-土-桥墩相互作用非线性数值分析模型

基于OpenSees数值分析平台,建立了群桩-土-桥墩非线性数值分析模型。模型中桩-土水平向相互作用和桩-土竖向相互作用、桩底-土竖向相互作用分别通过p-y、t-z与q-z零长度弹簧单元模拟。模型中同时考虑了群桩效应与纵筋在墩底的应变渗透和粘结滑移的影响。结合群桩基础拟静力试验结果,对数值模型的准确性进行了验证,在此基础上对土体参数特性对桩基滞回性能的影响规律进行了分析。结果表明:所建立的数值分析模型可对群桩基础滞回曲线和骨架曲线进行较为准确的模拟分析,验证了模型的可靠性。反复荷载作用下,前桩处土体的反应明显大于中桩处;土体由软黏土变为硬黏土时,墩顶侧向承载力与刚度显著增加,但土体的非线性反应减弱。     

复杂地基条件下桩-土-核岛结构相互作用模型研究

合理有效地模拟桩-土-结构动力相互作用是软土地基条件下核岛厂房结构抗震适应性分析及地基处理的关键环节。以某拟建核岛厂房实际工程为研究背景,结合SuperFLUSH软件平台,以Goodman单元模拟桩与桩周土间的接触效应,采用等价线性法描述近场软土地基非线性特性,并在模型底部和侧面引入黏性边界模拟半无限地基辐射阻尼效应,从而建立土质地基条件下桩-土-核岛结构相互作用分析模型。进而,通过对原状地基和嵌岩桩处理地基条件下核岛厂房的楼层反应谱、结构节点相对位移（绝对值）的对比分析,探讨考虑桩-土间接触效应的嵌岩桩基对核岛厂房结构的影响规律。研究成果可为实际工程中类似土质地基条件下核岛厂房结构的地基处理提供参考。     

横向非一致地震激励下埋地管道的动力响应分析

为研究埋地管道在地震激励时管-土相互作用的动力响应问题,研发双向层状剪切连续体模型土箱,建立管G土相互作用有限元分析模型,对横向非一致地震激励下埋地管道地震响应进行数值模拟分析,并与试验结果进行对比.结果表明:数值模拟和振动台试验结果中的管道应变峰值均呈现出沿管道中间大两端小的现象,管道中间应变峰值最小达到两端的1．6倍左右;管道加速度、 土体加速度峰值均随着加载等级的提高而增大,涨幅愈加明显,多峰频率由0~10Hz逐渐向10~ 20Hz频域扩散,管道运动更为自由;土体位移随着加载等级的提高呈现逐级增大的现象,在加载等级增加到0．4g 时位移曲线斜率减小,土体非线性表现明显.数值模拟和振动台试验对比分析的结论表明数值模拟分析的合理性和试验结果的可靠性,为研究横向非一致激励对埋地管道地震响应的影响提供了依据.     

Real-time dynamic hybrid testing for soil–structure interaction analysis

Simulating dynamic soil–structure interaction (SSI) problems is a challenge when using a shaking table because of the semi-infinity of soil foundations. This paper develops real-time dynamic hybrid testing (RTDHT) for SSI problems in order to consider the radiation damping effect of the semi-infinite soil foundation using a shaking table. Based on the substructure concept, the superstructure is physically tested and the semi-infinite foundation is numerically simulated. Thus, the response of the entire system considering the dynamic SSI is obtained by coupling the numerical calculation of the soil and the physical test of the superstructure. A two-story shear frame on a rigid foundation was first tested to verify the developed RTDHT system, in which the top story was modeled as the physical substructure and the bottom story was the numerical substructure. The RTDHT for a two-story structure mounted on soil foundation was then carried out on a shaking table while the foundation was numerically simulated using a lumped parameter model. The dynamic responses, including acceleration and shear force, were obtained under soft and hard soil conditions. The results show that the soil–structure interaction should be reasonably taken into account in the shaking table testing for structures.     

考虑SSI效应储油罐的子结构实验方法与数值模拟

提出了应用振动台子结构试验方法来研究考虑土-结构相互作用（SSI）效应储罐的抗震性能,该方法将土体简化为双自由度八参量集总参数模型进行模拟,储罐作为试验子结构应用振动台加载,两部分联机完成振动台子结构试验。该方法能完成大比例尺储罐试验,具有传统试验方法难以比拟的优势。然后,通过数值模拟分析了SSI效应对储罐动力响应的影响。分别研究了不同储液高度和不同地基刚度对储罐位移和加速度响应的影响。研究结果表明：考虑SSI效应时,罐体位移响应和加速度响应均有所减小,土质越软,效果越明显;随着储液高度的增高,位移、加速度反应呈现减小趋势。     

Real-time dynamic hybrid testing for soil–structure interaction analysis

Simulating dynamic soil–structure interaction (SSI) problems is a challenge when using a shaking table because of the semi-infinity of soil foundations. This paper develops real-time dynamic hybrid testing (RTDHT) for SSI problems in order to consider the radiation damping effect of the semi-infinite soil foundation using a shaking table. Based on the substructure concept, the superstructure is physically tested and the semi-infinite foundation is numerically simulated. Thus, the response of the entire system considering the dynamic SSI is obtained by coupling the numerical calculation of the soil and the physical test of the superstructure. A two-story shear frame on a rigid foundation was first tested to verify the developed RTDHT system, in which the top story was modeled as the physical substructure and the bottom story was the numerical substructure. The RTDHT for a two-story structure mounted on soil foundation was then carried out on a shaking table while the foundation was numerically simulated using a lumped parameter model. The dynamic responses, including acceleration and shear force, were obtained under soft and hard soil conditions. The results show that the soil–structure interaction should be reasonably taken into account in the shaking table testing for structures.     

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.     

Full-scale model testing on a ballastless high-speed railway under simulated train moving loads

Model testing in laboratory, as an effective alternative to field measurement, provides valuable data to understand railway׳s dynamic behaviors under train moving loads. This paper presents comprehensive experimental results on track vibration and soil response of a ballastless high-speed railway from a full-scale model testing with simulated train moving loads at various speeds. A portion of a realistic ballastless railway comprising slab track, roadbed, subgrade, and subsoil was constructed in a larger steel box. A computer-controlled sequential loading system was developed to generate equivalent vertical loadings at the track structure for simulating the dynamic excitations due to train׳s movements. Comparisons with the field measurements show that the proposed model testing can accurately reproduce dynamic behaviors of the track structure and underlying soils under train moving loads. The attenuation characteristics of dynamic soil stresses in a ballastless slab track is found to have distinct differences from that in a ballasted track. The model testing results provide better understanding of the influence of dynamic soil–structure interaction and train speed on the response of track structure and soils.     

Effects of soil cracking on the seismic response of soil–structure systems

A numerical study on the influence that cracks and discontinuities (closed cracks) can have on the seismic response of a hypothetical soil–structure system is presented and discussed. A 2-D finite-difference model of the soil was developed, considering a bilinear failure surface using a Mohr–Coulomb model. The cracks are simulated with interface elements. The soil stiffness is used to characterize the contact force that is generated when the crack closes. For the cases studied herein, it was considered that the crack does not propagate during the dynamic event. Both cases, open and closed cracks, are considered. The nonlinear behavior was accounted for approximately using equivalent linear properties calibrated against several 1-D wave propagation analyses of selected soil columns with variable depth to account for changes in depth to bed rock. Free field boundaries were used at the edges of the 2-D finite-difference model to allow for energy dissipation of the reflected waves. The effect of cracking on the seismic response was evaluated by comparing the results of site response analysis with and without crack, for several lengths and orientations. The changes in the response obtained for a single crack and a family of cracks were also evaluated. Finally, the impact that a crack may have on the structural response of nearby structures was investigated by solving the seismic-soil–structure interaction of two structures, one flexible and one rigid to bracket the response. From the results of this investigation, insight was gained regarding the effect that discontinuities may have both on the seismic response of soil deposits and on nearby soil–structure systems.     

Evaluation of the effect of earthquake frequency content on seismic behavior of cantilever retaining wall including soil–structure interaction

A three-dimensional backfill–structure–soil/foundation interaction phenomenon is simulated using the finite element method in order to analyze the dynamic behavior of cantilever retaining wall subjected to different ground motions. Effects of both earthquake frequency content and soil–structure interaction are evaluated by using five different seismic motions and six different soil types. The study mainly consists of three parts. In the first part, following a brief review of the problem, the finite element model with viscous boundary is proposed under fixed-base condition. In the second part, analytical formulations are presented by using modal analysis technique to provide the finite element model verification, and reasonable agreement is found between numerical and analytical results. Finally, the method is extended to further investigate parametrically the effects of not only earthquake frequency content but also soil/foundation interaction, and nonlinear time history analyzes are carried out. By means of changing the soil properties, some comparisons are made on lateral displacements and stress responses under different ground motions. It is concluded that the dynamic response of the cantilever wall is highly sensitive to frequency characteristics of the earthquake record and soil–structure interaction.