Seismic Liquefaction Resistance Based on Strain Energy Concept Considering Fine Content Value Effect and Performance Parametric Sensitivity Analysis

Liquefaction is one of the most destructive phenomena caused by earthquakes,which has been studied in the issues of potential,triggering and hazard analysis.The strain energy approach is a common method to investigate liquefaction potential.In this study,two Artificial Neural Network(ANN)models were developed to estimate the liquefaction resistance of sandy soil based on the capacity strain energy concept(W)by using laboratory test data.A large database was collected from the literature.One group of the dataset was utilized for validating the process in order to prevent overtraining the presented model.To investigate the complex influence of fine content(FC)on liquefaction resistance,according to previous studies,the second database was arranged by samples with FC of less than 28%and was used to train the second ANN model.Then,two presented ANN models in this study,in addition to four extra available models,were applied to an additional 20 new samples for comparing their results to show the capability and accuracy of the presented models herein.Furthermore,a parametric sensitivity analysis was performed through Monte Carlo Simulation(MCS)to evaluate the effects of parameters and their uncertainties on the liquefaction resistance of soils.According to the results,the developed models provide a higher accuracy prediction performance than the previously publishedmodels.The sensitivity analysis illustrated that the uncertainties of grading parameters significantly affect the liquefaction resistance of soils.

Correlation of liquefaction resistance with shear wave velocity based on laboratory study using bender element

Recent studies using field case history data yielded new criteria for evaluating liquefaction potential in saturated granular deposits based on in situ, stress-corrected shear wave velocity. However, the conditions of relatively insufficient case histories and limited site conditions in this approach call for additional data to more reliably define liquefaction resistance as a function of shear wave velocity. In this study, a series of undrained cyclic triaxial tests were conducted on saturated sand with shear wave velocity Vs measured by bender element. By normalizing the data with respect to minimum void ratio, the test results, in-corporated with previously published laboratory data, statistically revealed good correlation of cyclic shear strength with small-strain shear modulus for sandy soils, which is almost irrespective of soil types and confining pressures. The consequently determined cyclic resistance ratio, CRR, was found to be approximately proportional to Vs4. Liquefaction resistance boundary curves were established by applying this relationship and compared to liquefaction criteria derived from seismic field measure-ments. Although in the range of Vs1>200 m/s the presented curves are moderately conservative, they are remarkably consistent with the published field performance criteria on the whole.

Study on Wave-influenced resistance to erosion of silty soil in Huanghe (Yellow) River Delta

Along with the reduction of sediment yield of the Huanghe （Yellow） River, the erosion of the Huanghe River Delta aggravates, which has becomes an important factor that threatens the coastal protection structures. Starting from the study of the erosion resistibility of the sediment, this paper explores the internal mechanism of erosion phenomenon. This paper takes Diaokou as the study area and takes soils as samples which are mixed with clay into reconstructed samples whose ratio of clay content are 5%, 10%, 15%, 20% respectively, then dynamic tri-axial apparatus is applied to simulate wave loads of different intensity; then the resistibility of soil to erosion is determined via concentrated flow test and the structural property is determined via the disintegration test. Finally, the resistibility to erosion and the structural property of the non-compressed soil samples are compared with the compressed data. The results indicates that liquefaction failure exerts significant influence on the resistibility to erosion and the structural property of the silty soil in the Huanghe River Delta. Therefore, in the future erosion studies, the liquefaction phenomenon shall be fully considered.

Liquefaction Assessment in Golem Area, Albania, by Means of In-situ Tests

The liquefaction is a very significant phenomenon in clayey silty soils, silty sands and also sands. The high potential of liquefaction is generally recognized when these types of soils are laid under the hydrostatic water table. Low plasticity silts, silty sands and sands are found as recent alluvial deposits in the western coastal part of Albania, especially in the sandy beaches of Adriatic Sea near Durres City. The aim of this study is to evaluate the soil liquefaction potential in the area of Golem. Ten CPTUs （cone penetration test with pore pressure measurements） are carried out for the site investigation of soils. In this paper, results of the CPTU based liquefaction analysis are presented. The data of two CPTUs （10 in total） are analyzed and factor of safety was found by considering different levels of hazard and ground water. The results of liquefaction potential analysis show that the soils in the area of Golem have a high risk of liquefaction.

Soil Liquefaction Hazard Evaluation by the New Seismic Dilatometer Marchetti Test （SDMT）

Soil liquefaction, and the permanent deformations that frequently result from it, have caused significant damage in past earthquakes. The procedures used in contemporary geotechnical earthquake engineering practice are generally based on simplified procedures for the evaluation of the liquefaction potential. The work describes a framework for performance-based earthquake engineering and its use in the development of a performance-based procedure for liquefaction hazard evaluation. The performance-based procedure will be used to show how consistent application of conventional procedures for evaluation of liquefaction potential can influence performance prediction. Implications for liquefaction-resistant design will also be discussed. The purpose is to summarize current procedures for practical prediction of liquefaction behavior, to describe recent advances in the understanding of liquefaction behavior, and to describe the incorporation of this improved understanding into new solutions for detailed modeling of soil liquefaction, Simplified procedures for evaluation of liquefaction hazards will be reviewed relatively briefly, with more details devoted to emerging knowledge about the mechanics of liquefiable soil behavior, and methods for incorporating those mechanics into improved models for performance prediction. In particular it focuses about the influence on the evaluation of Cyclic Resistance Ratio （CRR） by different in-situ tests （Cone Penetration Test （CPT）. Standard Penetration Test （SPT） and Seismic Dilatometer Marchetti Test （SDMT）） and by different shear waves velocity measurements （Down Hole D-H. Cross Hole C-H, Seismic Dilatometer Marchetti Test SDMT）.

纳米硅溶胶改良辽宁台安砂土的抗液化性能研究

辽宁台安砂土属于易液化砂,提升其抗液化性能具有重要的工程意义。文章针对纳米硅溶胶(CS)对辽宁台安砂土抗液化性能的改良效果进行探究,通过不排水动三轴试验,对纯砂样和改良砂样的液化特性进行对比研究,分析CS浓度和固化时间两个参量对改良砂样动力特性的影响。研究结果表明:(1)CS能够显著提升台安砂土的抗液化性能,在动载作用下改良砂样均未发生液化破坏。(2)随CS浓度和固化时间的增加,试样动孔压u_(d)、动应变ε_(d)呈现先迅速下降后趋于平缓的发展规律;当CS浓度增至4%、固化时间达到3周后,试样抗液化性能的提升效果不再明显。(3)改良砂样的滞回曲线变得更加稳定。随CS浓度增加,阻尼先降低后趋于稳定,动弹性模量逐渐增大并趋于平缓,但伴随有一定的波动;随固化时间增大,阻尼呈减小趋势,动弹性模量呈增大趋势。研究成果可为辽宁台安地区砂土液化治理提供参考依据。

微生物分解硅酸盐矿物增黏对砂土强度的影响

砂土因其无黏聚力而易导致地震液化和渗流侵蚀等工程病害问题,微生物矿化与分解技术的发展为提高砂土黏聚力提供了新的可能。利用胶质芽孢杆菌能够分解硅酸盐矿物的特性,采取人工营养液激励加速含钾长石、黑云母等硅酸盐矿物砂土的生物风化,分析经微生物处理前后砂土的强度参数、黏粒含量、矿物组分和粒间微结构的变化规律。结果表明:胶质芽孢杆菌处理后的砂土中黏粒含量增加了1.6%;黏聚力与处理时长呈线性正相关,120 d内有效黏聚力增加了23 kPa,有效内摩擦角则有轻微的减小;砂土中的钾长石、黑云母等硅酸盐矿物均产生了不同程度的分解破坏,X射线衍射谱图显示,微生物处理120 d后砂土中出现了新的高岭石衍射峰,表明胶质芽孢杆菌分解了黑云母和钾长石等硅酸盐矿物,产生次生黏土矿物高岭石,使砂土中黏粒含量增加。微生物分解硅酸盐矿物产生黏土矿物和胞外聚合物是砂土黏聚力提升的主要原因。营养物激励下矿物分解菌对硅酸盐矿物的风化作用对于改善砂土抗液化和抗渗流性能具有潜在的价值。

强震多发区液化地基均质坝抗震除险加固研究

鉴于强震多发区液化地基均质坝缺乏完整的抗震体系结构,坝体经常遭受地震破坏。为了提高坝体的整体抗震性能,以新疆西克尔水库为研究对象,对震害成因进行了分析,从提高坝体自身抗震、抑制孔隙水压力上升、抑制孔隙水侧向流动、提高止水适应性等方面进行了系统研究,提出了固-抑-束-补系统结合的液化地基土石坝抗震加固方法,采用ABAQUS有限元软件对抗震措施的有效性进行了验证分析。结果表明所采用的抗震体系结构能够有效抵御地震对坝体和建筑物的破坏,对类似工程具有良好的借鉴意义。

轮胎加筋砂垫层抗液化性能振动台试验研究

将废弃橡胶轮胎内填充散体材料形成加筋土结构,已被应用于地基、挡土墙和边坡加固等工程,表现出较好的减震隔振效果,而轮胎加筋土的抗液化性能尚缺乏研究。开展3组小型振动台试验,通过改变轮胎垫层的排水条件,验证轮胎加筋砂垫层的抗液化效果。结果表明:轮胎加筋砂垫层具有良好的抗液化效果,与刚性垫层相比,超静孔压比峰值差值范围在0.01~0.19,残余超静孔压比差值范围在0.08~0.16,轮胎加筋砂垫层提供的排水通道具有抑制超静孔隙水压力发展和加速超静孔隙水消散的作用,孔隙水会沿着轮胎与下部土体的界面以及胎间的排水通道排出;采用量测侧向动土压力的方法,定义土体液化程度量化指标,进一步验证轮胎加筋砂垫层抗液化效果;振动过程中轮胎加筋垫层表面沉降范围为11.3~15.7 mm,表现出较好的变形协调性能。

地震多发区尾矿抗液化强度与动力变形特性试验

为了研究地震多发区尾矿的抗液化强度和动力变形特性,以某上游法尾矿库中尾矿为研究对象,首先探究沉积固结方式与尾矿细粒含量(FC)的关系;此外,通过开展动三轴试验研究FC对尾矿抗液化性能和动力变形特性的影响,并从尾矿的微观结构特征出发,分析FC对尾矿动力变形特性的作用机制.结果表明:上层尾矿主要经历淋滤固结和化学固结,下层尾矿主要经历自重固结,而FC随取样深度非线性增加.对数坐标下的动剪应力随动循环次数增加近似线性减小,而有效固结围压(σ′_(3c))增大使尾矿颗粒接触更加紧密,导致尾矿结构破坏需要更强的动载荷.尾矿的抗液化强度随FC增加先降低后升高,FC越小,尾矿的抗液化强度越高、循环应力比衰减越快,而FC变化对动孔隙水压比的影响较小.尾矿的动孔隙水压比–振次比曲线呈现“减速增长—稳定增长—加速增长”的3阶段发展趋势,而较大的固结压力能够在一定程度上抑制动孔隙水压增长,此外,基于三参数动孔隙水压模型,得到了适用于本文尾矿的两参数动孔隙水压简化模型.随着FC增大,尾矿的动剪切模量先减小后增大、阻尼比先增大后减小,尾矿的动力变形特性逐渐由粗颗粒控制向细颗粒控制转变,该过程细粒含量存在临界值.研究结果可为地震多发区尾矿库稳定性评价及尾矿动力分析提供理论依据.

土工布加筋砂土场地抗液化数值模拟

以往的试验研究表明土工布加筋可以有效缓解饱和砂土的振动液化。针对饱和砂土抗液化研究,过去的研究手段往往局限于室内动三轴试验,而缺乏对土工布加筋砂土场地的抗液化研究。首先结合土工布加筋砂土抗液化动三轴试验结果,对不同的土工布加筋砂土进行了参数标定。在此基础上,利用开源有限元数值模拟平台OpenSees,对不同土工布加筋工况下的饱和砂土场地开展抗液化数值模拟研究。结果表明,土工布加筋能够降低砂土场地的超孔压和位移,砂土场地的抗液化性能随着土工布层数的增加而提升。这种通过参数标定法来实现土工布加筋砂土数值建模的技术,可为类似加筋土层的数值模拟提供一些有价值的参考与借鉴。

某地区非饱和粉土抗液化强度的试验研究

以往研究表明液化主要发生在饱和土中,但对于非饱和粉土也有液化现象发生。本文利用《建筑抗震设计规范》(GB 50011-2010)中的“标贯法”对山东省乐陵市的非饱和粉土液化程度进行判别,并引用Andrus提出的抗液化应力比CRR (cyclic resistance ratio),对乐陵市非饱和粉土进行分析研究。研究结果表明:16个试验点中接近70%的试验点被判断为液化点;对于埋深小于7 m的非饱和粉土,其孔隙比是影响液化的一个重要因素,孔隙比与抗液化能力呈现出较好的相关性;在7 m内的埋深范围内,浅层的非饱和粉土抗液化能力更强;当埋深超过某一深度界限(7~9 m)时,孔隙比对抗液化能力的影响较小,埋藏深度的影响较为显著,深度大的非饱和粉土的抗液化能力更强。研究结果为工程中判断非饱和粉土液化及其影响因素提供参考。

纤维及土工布对加固砂土抗液化性能的影响研究

为了研究纤维及土工布等加固材料对饱和砂土抗液化性能的影响,采用应变控制条件下的不排水动三轴试验,制备了加固后的饱和砂土试样,分析不同循环剪应变幅值、纤维含量和土工布层数对加固效果的影响。研究结果表明,随着循环剪应变幅值的增大,超孔隙水压累积速度显著加快,同时平均有效应力的衰减速度也加快,导致饱和砂土抗液化能力显著降低;超孔隙水压的累积速度随着纤维含量的增加而显著减缓,表明掺入纤维对饱和砂土抗液化的增强效果显著;纤维含量为0.3%的砂土的液化时间相比含量为0时延缓77.3%;随着土工布层数增加,超孔压累积速率、有效应力衰减速率下降,砂土抗液化及抗剪切性能提升。

碎石桩处理液化地基抗液化研究现状及存在问题

就目前国内外碎石桩处理液化地基抗液化理论、动力分析以及液化判别等方面的研究作简要的归纳和评述。在加固机理研究方面,主要认为碎石加固砂土有以下几种作用:(1)挤密作用;(2)振密作用;(3)排水减压作用;(4)预震作用;(5)加筋作用。其次,在理论研究方面如排水效应和桩体效应方面的研究也取得了长足进展,已经从总应力法深入到有效应力法,从只对孔压的研究发展到对水土共同作用的研究。并且随着计算机的发展,数值计算为复杂条件下的问题解答开辟了一个新的途径,现在已经可以模拟地震时土体的变形和孔压变化情况。但是在碎石桩处理液化地基的判别标准研究方面发展较慢。最后,对高速公路碎石桩复合地基抗液化研究方面的一些不足之处提出了解决的思路,主要包括:(1)上部荷载对复合地基的影响;(2)碎石桩处理深度设计时应考虑的影响因素;(3)碎石桩加固区与周围环境的相互作用;(4)考虑碎石桩排水、应力集中和附加应力共同影响下的液化判别标准。

粘粒含量对砂土静动力液化影响的试验

含一定粘土颗粒的砂土在一定条件下易发生静态和动力液化的现象,且粘土对砂土的抗液化影响规律较为复杂。为了研究粘粒含量对砂土液化的影响规律,通过静力三轴仪和动力三轴仪试验系统,对粘粒含量分别为0%、5%、10%和15%的砂土进行试验。静力与动力的试验结果表明：粘粒含量对砂土抗液化性能的影响并不是单调的,存在一个粘粒含量值（5%~10%）使得砂土的抗液化性能最差。当粘粒含量小于5%时,粘粒会促进孔压的发展;当粘粒含量大于10%时,粘粒会抑制孔压的发展。不同含量的粘粒在砂土颗粒间分别起到润滑与粘结砂粒的作用。

基于电阻率CPTU的饱和砂土液化势评价研究

饱和砂土的液化是地基基础震害的主要原因之一,对饱和砂土的液化势进行有效的评估是非常重要的。由于获得无扰动试样的困难和成本限制,原位测试方法通常用于砂土液化势的评价。目前出现了许多基于静力触探的液化评估方法,然而还没有出现哪一种方法最可靠的结论,高风险项目中通常采用多种方法进行综合评估,而新的液化评估方法的研究是非常有意义的。以宿迁—新沂高速公路建设为工程背景,采用电阻率孔压静力触探(RCPTU)对饱和粉质砂土进行了土层电阻率测试。首先,分析了归一化锥尖阻力与电阻率的关系,对建立电阻率液化评估方法具有指导意义。其次,以Robertson修正方法给出的周期阻力比为参考值,研究了联合电阻率和土类指数的周期阻力比计算方法,并研究了薄黏土层和过渡层对本文所提出电阻率方法的影响。结果表明,采用电阻率和土类指数能够对饱和砂土的液化势进行有效评估,然而应用于薄黏土层和过渡层时会低估土的周期阻力比。

汶川地震中道路边坡工程震害分析

发生在山区的地震对边坡工程所造成的危害,在致灾机制和破坏形式方面具有鲜明的特征。结合汶川地震灾区道路边坡工程震害实例,分析路堑、路堤以及与桥隧相连的各类边坡及相应支挡结构的震害机制和破坏形式。锚索(杆)地梁或预应力锚索抗滑桩加固的边坡具有较好的抗震性能,其原因是这些结构已与坡体联接在一起而形成一个整体,在地震波作用下结构与坡体的位移和变形能够很好地协调一致。铺设土工格栅或施加加筋材料的路堤边坡工程具有较好的抗震性能,一般填筑路堤特别是高路堤,其抗震性能较差。根据沙土液化和软弱黏性土层震陷造成的震害实例,提出含水沙质地层路堤边坡应注意坡脚沙土液化造成的震害,应采取措施防止软弱黏性土层地基震陷造成路面破坏以及坡脚震陷造成的边坡失稳。山区隧道洞口边、仰坡的抗震设计应重视支挡结构的耐震性。建于坡体上的桥台、桥基和桥路过渡段的安全性与坡体稳定性直接相关,应切实加强这些结构所在边坡的抗震设计。对于依山傍水而建的顺河桥,相关边坡的失稳危害桥梁时,应对其采取抗震措施。目前公路、铁路工程抗震规范涉及边坡工程及支挡结构的内容极少,研究成果可为规范的修改和补充提供有益的参考。

可液化地基上建筑物不均匀震陷机制的振动台试验研究

设计实现了液化土–结构相互作用的振动台试验,试验包括地震波输入大型振动台试验和正弦波输入小型振动台试验。试验中建筑物模型和地基土均匀布置,输入单方向水平加速度时程,得到了建筑物对称基底动应力、孔压及建筑物对称顶点的不均匀震陷。研究结果表明:(1)模型对称基底的竖向动应力易呈反对称形式分布;(2)模型基底竖向动压应力对孔压增长有较大贡献;(3)输入波形不对称的地震波能够导致模型对称基底孔压分布不均衡及建筑物不均匀震陷;(4)输入正弦波,模型对称基底动应力及孔压差别不明显,模型将发生均匀震陷。

砂砾土抗液化强度的小型土箱振动台试验研究

近来数次大地震中出现大量的砂砾土液化震害,饱和砂砾土的地震液化问题越来越引起重视。针对砂砾土的抗液化强度问题,开展了4种砾含量、3种相对密度情况下,饱和砂砾土的小型土箱振动台试验研究。为获得较为合理的抗液化强度结果修正了由加速度计倾斜产生的加速度时程漂移,并描述了土体中加速度和动孔压发展特性。饱和砂砾土的抗液化强度结果显示:含砾量和相对密度对饱和砂砾土的抗液化强度均有明显影响。饱和砂砾土的抗液化强度随着含砾量和相对密度的增加明显增大,增大的趋势越来越明显,且明显高于相近相对密度的饱和砂土的抗液化强度。

细粒含量对尾矿材料液化特性的影响

为了模拟沉积分选后颗粒组成的变化对尾矿材料的动力特性的影响,尾矿筛分后按不同的细粒(颗粒直径小于0.074 mm)含量制备尾矿试样,并进行了大量的土动力学试验。分析了细颗粒含量对尾矿材料的动力液化特性的影响规律。研究表明,对于铜矿类尾矿坝的尾矿材料,当细颗粒含量占到总量的35%时其抗液化性能最佳。根据尾矿材料动力特性试验的研究结果,并结合现场的标准贯入试验成果,提出了适用于尾矿材料的细粒含量对标准贯入击数的修正式。该式可以分析不同细粒含量的尾矿材料的抗液化强度,提高尾矿坝液化判别方法的判别准确程度。