断层错动引起的上覆土体破裂演化规律研究

断层引起的地面永久大变形是工程特别是生命线工程地震破坏的重要原因之一, 而研究断层错动下上覆土体变形和破裂的发展演化规律, 则是预测地面永久变形状态和分析断层危害性的基础． 本文采用有限元方法对垂直断层错动引起的上覆土体破裂演化规律进行了研究, 建立了垂直断层作用下上覆土体模拟的有限元模型, 对断层错动作用下上覆土体的破裂发展过程进行了模拟分析, 并分析了加载速率、 土体特性及断层倾角等参数对上覆土体的破裂演化发展过程的影响． 结果表明: ① 断层倾角越陡, 地表出现破裂时需要增加的垂直位移越大; ② 由于惯性力的影响, 断层加载速率对地表破裂所需施加位移和土层破裂角产生一定的影响; ③ 断层类型对土层地表破裂角与膨胀角、 摩擦角之间的关系有很大影响． 该分析结果可为新建工程的抗震设计和已建工程结构的抗震加固等工作提供依据．      

隐伏正断层错动致地表破裂变形特征的研究

通过建立三维计算模型,对隐伏正断层在均匀错动、倾斜错动和翘倾错动方式下地表土体的应力路径、破裂和变形特征进行了研究。根据地表破裂临界值,分析了工程建设“避让带”的宽度和起始位置的变化特征。根据行业规范,提出工程建设“关注带”的确定方法,分析了“关注带”的宽度和起始位置的变化特征,得到以下主要结论:①在断层错动过程中,位于两侧的地表土体应力路径变化明显不同,下盘一侧和上盘一侧分别以三轴拉伸和三轴压缩为主;②地表强变形带与地表破裂带的分布并不一致,需要综合考虑等效塑性应变和总位移比2个指标来评价同震地表错动对建筑物的影响;③当隐伏断层错动的垂直位移达到3m时,工程建设“避让带”的宽度在10—90m范围内变化,受上覆土体厚度和断层倾角的影响最大,而工程建设“关注带”的宽度在150—400m范围内变化,受上覆土体的性质影响最大。     

Influence factors on the ground surface rupture zone induced by buried normal fault dislocation*

The seismic disaster presents a zonal distribution along the fault strike. In this paper, rupture zone of ground surface soil caused by the uniform dislocation, inclined dislocation and warped dislocation of buried normal fault are studied by constituting a three-dimensional finite element model in Automatic Dynamic Incremental Nonlinear Analysis (ADINA). According to the critical value of surface rupture, the variational features and influencing factors of width and starting position of the “avoiding zone” in engineering construction are analyzed by using 96 model calculations. The main results are as follows: (1) Since the rupture zone of the ground surface soil from the point of mechanics is different from the “avoidance zone” from the point of engineering safety, the equivalent plastic strain and the total displacement ratio should be considered to evaluate the effect of the seismic ground movement on buildings. (2) During fault dislocation, plastic failure firstly occurred on the ground surface soil of the footwall side, and then the larger deformation gradually moved to the side of the hanging wall of the fault with the increase of fault displacement. (3) When the vertical displacement of buried fault reaches 3 m, the width of “avoiding zone” in engineering construction varies within the range of 10–90 m, which is most affected by the thickness of overlying soil and the dip angle of the fault.     

隐伏正断层错动引发上覆土体破裂过程的三维数值模拟

通过建立三维数值模型,对隐伏正断层在均匀错动和倾斜错动方式下土体的破裂过程进行研究。利用应力罗德参数和等效塑性应变分别对断层错动过程中上覆土体的应力状态和破坏形式进行分析,并提出土体破裂的判别方法。通过对数值模拟结果的分析得到以下结论:① 在断层错动过程中,下盘一侧受断层错动影响的上覆土体的应力状态经压剪→纯剪→拉剪逐渐变化,而上盘一侧上覆土体的应力状态变化较为复杂,经压剪→纯剪→拉剪→纯剪→压剪重复变化;② 在断层均匀错动过程中,断层下盘一侧土体的破裂率先出现在地表拉剪区内,随错动量的增大,破裂带向两侧、向深部扩展;同时,下盘一侧土体的底部产生破坏,并斜向上扩展,逐渐与顶部破裂相连;③ 在断层倾斜错动过程中,地表破裂出现的位置和上覆土体的厚度有关。对于厚度较大的土体,正断层倾斜错动能够在地表形成与断层走向有一定夹角、且与断层长度相比长度很短的地表破裂或地裂缝,而数值模拟可对正断层错动导致的地表破裂的模式加以补充,为研究地裂缝的形成机理和分布形式提供依据。      

穿越走滑断层海底管道局部屈曲研究及应变响应预测

海洋地震频繁且海底土体环境复杂,当地震导致断层土体发生永久变形后,穿越断层的海底埋地管道也将受迫发生变形。为确定变形后的管道能否正常工作,需根据实际工况对其进行应变响应预测。首先通过有限元计算软件ABAQUS建立管道与走滑断层的三维实体模型,模拟管-土间的接触作用并通过等效边界方法修正模型,得到管道局部屈曲破坏形式及应变分布情况。然后,通过调整有限元模型参数对断层交角、管道工作内压、管道径厚比对管道极限塑性应变的影响进行敏感性分析,定性分析不同敏感性因素对穿越走滑断层海底管道应变响应的影响。最后,在数值模拟数据的基础上通过MATLAB软件利用基于遗传算法优化的BP神经网络实现对管道应变响应的精确预测。结果表明:穿越走滑断层管道在发生局部屈曲时,可根据轴向压缩应变突变现象确定管道局部屈曲时对应的断层位移,并且断层交角、管道工作内压和管道径厚比都会对跨断层管道应变响应产生影响。     

地震断层对管道压溃压力的影响

利用有限元软件ABAQUS,结合用户自定义Python程序,开展地震断层作用下深海管道局部变形和压溃过程的数值模拟。分析均质土体和随机分布土体模型的地震断层位移大小对管道局部变形的影响,并分析断层诱发的局部挤压变形对管道压溃压力的影响。研究表明:相比于断层走向与管道轴线方向垂直的走滑断层,断层走向与管道轴线方向夹角为45°的走滑断层作用下管道的压溃压力较小,且当断层走向为管道轴线方向逆时针旋转45°时,左旋走滑断层作用下管道的压溃压力低于右旋走滑断层作用下的管道压溃压力。断层位移相同时,管道径厚比越大,压溃压力越小。考虑土壤随机性时,由于APIX65钢制管道刚性较大,且管道两侧土体内聚力和摩擦角分散于均质土壤土体参数均值两侧,因此断层作用过程中管道受到的土压力在均质土壤模型中的土压力数值处上下波动。     

地震作用下埋地弯管变形传递系数分析

由于管道与土体的刚度相差较大,在振动荷载下,两者的运动不能相互协调,致使在研究管道破坏方面,管土之间的变形传递是一个极其重要的研究方向.目前学者对弯管的管土变形传递研究做得较少.本文通过弯管与土体的缩尺振动台试验及三维有限元模型,得出了地震作用下埋地弯管的变形传递系数的拟合公式.然后将试验结果与拟合公式的计算结果和有限...     

Centrifuge modeling of buried continuous pipelines subjected to normal faulting

Seismic ground faulting is the greatest hazard for continuous buried pipelines.Over the years,researchers have attempted to understand pipeline behavior mostly via numerical modeling such as the finite element method.The lack of well-documented field case histories of pipeline failure from seismic ground faulting and the cost and complicated facilities needed for full-scale experimental simulation mean that a centrifuge-based method to determine the behavior of pipelines subjected to faulting is best to verify numerical approaches.This paper presents results from three centrifuge tests designed to investigate continuous buried steel pipeline behavior subjected to normal faulting.The experimental setup and procedure are described and the recorded axial and bending strains induced in a pipeline are presented and compared to those obtained via analytical methods.The influence of factors such as faulting offset,burial depth and pipe diameter on the axial and bending strains of pipes and on ground soil failure and pipeline deformation patterns are also investigated.Finally,the tensile rupture of a pipeline due to normal faulting is investigated.     

穿越克孜尔逆冲断层的输气管道抗震分析

输气管道作为1种薄壁壳体结构,逆冲断层引起的管道压缩变形容易使其破坏。本文以大北南疆输气管道工程为例,探讨了穿越克孜尔逆冲断层的输气管道地震安全问题。在确定管道穿越处的断层倾角、设防断层位错量、表征管土相互作用的土弹簧参数以及钢管容许应变等参数后,采用壳有限元方法,分析了穿越克孜尔逆冲断层的输气管道变形反应。分析结果显示,管道在逆冲断层作用下以压缩应变为主,管道内的最大轴向压缩应变的幅值随着交角的减小而减小。在通过探槽等方法确定断层活动位置后,该管道若以小于或等于11°的交角通过克孜尔断裂,断层引起的最大轴向压缩应变和拉伸应变均在管道相应的容许应变范围内,满足相关规范的抗震要求。     

管土动力相互作用分析

相互作用问题是地下管线动力分析中的重点和难点。本文借助于大型有限元软件ABAQUS/Standard中的管土相互作用单元(Pipe-soil interaction element,简称PSI单元)并利用直剪试验实测的接触面本构关系,对管线与土体之间的相互作用进行了数值模拟研究,计算得到了地下管线在动力作用下的内力和变形。分析结果与试验结果的对比表明,本文方法具有良好的计算精度,对地下管线的分析和设计具有参考意义。     

Seismic wave propagation effects on buried segmented pipelines

This paper deals with seismic wave propagation effects on buried segmented pipelines. A finite element model is developed for estimating the axial pipe strain and relative joint displacement of segmented pipelines. The model accounts for the effects of peak ground strain, shear transfer between soil and pipeline, axial stiffness of the pipeline, joint characteristics of the pipeline, and variability of the joint capacity and stiffness. For engineering applications, simplified analytical equations are developed for estimating the maximum pipe strain and relative joint displacement. The finite element and analytical solutions show that the segmented pipeline is relatively flexible with respect to ground deformation induced by seismic waves and deforms together with the ground. The ground strain within each pipe segmental length is shared by the joint displacement and pipe barrel strain. When the maximum ground strain is higher than 0.001, the pipe barrel strain is relatively small and can be ignored. The relative joint displacement of the segmented pipeline is mainly affected by the variability of the joint pullout capacity and accumulates at locally weak joints.     

Dynamic effects of surface fault rupture interaction with structures

Surface fault rupture has caused significant damage to structures in several earthquakes. The propagation of the bedrock fault rupture through the overlying soil deposit has been studied by several researchers; however, the effects of fault rupture dynamics, as opposed to pseudostatic fault movement, have not yet been evaluated. There is the potential for dynamic effects to influence significantly structural damage due to the rapid rate of deformation imposed by surface fault rupture. Numerical simulations are performed to analyze the effects of the rate of fault rupture on dip-slip surface fault rupture for free-field and soil-structure interaction conditions. The numerical results indicate that in some limited scenarios, fault rupture dynamics can influence the amount of structural damage expected for a structure located near a fault. However, in most scenarios, fault rupture dynamics is expected to play a secondary role compared to fault, soil, and structural characteristics in evaluating building performance.     

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。     

有软夹层的基岩上覆土层在断层错动时的破裂特征研究

采用平面应变有限元法,研究了地震断层错动时有软夹层的基岩上覆土层的破裂特征. 结果表明,软夹层使上覆土层破裂分为两个阶段. 软夹层埋置深浅的不同使上覆土层的破裂过程和破裂范围表现出一定的差异. 埋置较深的软夹层使地表产生较大的破坏. 软夹层的厚薄对上覆土层的破裂进程和破裂范围也有影响.      

Study on the rupture characteristics of the overlaying soil with soft interlayer due to fault bedrock dislocation

Introduction A sudden rupture of fault in the crust induces intensive earthquake, and brings about the overlaying soil moving and cracking, and the Earth′s surface deforming and rupturing as well. When it crosses the foundations of buildings and the underground structures, the rupture close to the Earth′s surface or surface fault would lead to direct destruction to these structures. The study on this problem has been paid more attention in recent years. From Kobe Earthquake, Izimit Earthq…     

覆盖土层场地地震断裂反应分析方法

基于有限元和拟静力的根本原理，提出了一种基于断层位错的覆盖土层场地地震断裂反应弹塑性有限元分析方法，计算中考虑了土层厚度、断层种类和倾角、软弱夹层以及土的非线性等因素，通过编制的程序计算了地表断裂位移，模拟了土层的破裂过程。     

Permanent earthquake‐induced actions in buried pipelines: Numerical modeling and experimental verification

Buried pipelines are often constructed in seismic and other geohazard areas, where severe ground deformations may induce severe strains in the pipeline. Calculation of those strains is essential for assessing pipeline integrity, and therefore, the development of efficient models accounting for soil‐pipe interaction is required. The present paper is aiming at developing efficient tools for calculating ground‐induced deformation on buried pipelines, often triggered by earthquake action, in the form of fault rupture, liquefaction‐induced lateral spreading, soil subsidence, or landslide. Soil‐pipe interaction is investigated by using advanced numerical tools, which employ solid elements for the soil, shell elements for the pipe, and account for soil‐pipe interaction, supported by large‐scale experiments. Soil‐pipe interaction in axial and transverse directions is evaluated first, using results from special‐purpose experiments and finite element simulations. The comparison between experimental and numerical results offers valuable information on key material parameters, necessary for accurate simulation of soil‐pipe interaction. Furthermore, reference is made to relevant provisions of design recommendations. Using the finite element models, calibrated from these experiments, pipeline performance at seismic‐fault crossings is analyzed, emphasizing on soil‐pipe interaction effects in the axial direction. The second part refers to full‐scale experiments, performed on a unique testing device. These experiments are modeled with the finite element tools to verify their efficiency in simulating soil‐pipe response under landslide or strike‐slip fault movement. The large‐scale experimental results compare very well with the numerical predictions, verifying the capability of the finite element models for accurate prediction of pipeline response under permanent earthquake‐induced ground deformations.     

考虑土体固液二相性质的地下管线地震反应研究

本文将管线周围的土体视为固-液二相介质，采用考虑地震过程中土体内孔隙水压力的增长和消散的有效应力分析方法，并以非线性的土体本构模型模拟土体动力特性的改变以及在孔隙水压作用下的变形，以求接近土体的真实地震反应。研究表明随着土体软化程度的不同，受到土体约束的管线应力亦发生相应变化。文中详细研究了地震动峰值、管线直径、行波波速和入射角度等对管线应力的影响。     

不同土质条件下断层地表破裂对比研究

本文结合华北地区几个地震统计区的实例,探讨了地震统计区的重要地震活动性参数b值和v4不确定性的主要影响因素及其特征,并研究分析了其不确定性的大小。结果表明,地震活动性参数的不确定性主要影响因素为样本统计时段、样本处理方法、统计下限震级、高震级年平均发生率等。在郯庐地震统计区,b值变化可达0.2以上,v4的变化可达1.4以上,汾渭地震统计区的不确定性也基本相当,河北平原地震统计区因为地震样本相对丰富,不确定性要小许多。     

华北平原强震构造带与潜在震源区划分

在莫尔-库仑理论中引用Drucker-Prager准则,对于基岩断层及其上的覆盖土体建立相应的弹塑性模型,观察在不同力学条件下（张应力、压应力、剪应力）,以及在基岩断层分别为正断或逆断作用下,上覆粉砂质土体和粘土质土体的错动变形。结果表明：在张应力作用下,粘土比砂土更易变形;在压应力作用下,砂土更易变形;而在剪应力作用下,粘土比砂土更易变形,且粘土抗剪强度越大,变形越大。在正断层作用下,在粉砂土与粘性土中所发生的变形并没有大的不同,而在逆断层载荷作用下,粉砂质土体比粘土质土体更容易变形位错。