基于IDA的金安桥混凝土重力坝潜在失效模式研究

为了研究混凝土重力坝在地震动荷载作用下的潜在失效模式,以金安桥碾压混凝土重力坝5号非溢流坝段为例,运用粘弹性边界法和流固耦合法建立了反映重力坝在地震动作用下动力响应特征的坝体-地基-库水抗震分析模型。基于增量动力分析（IDA）法:绘制了以相对位移转角为x轴（损伤指标,DM）和峰值地面加速度为y轴（强度指标,IM）的IDA曲线簇;分析了金安桥大坝在极端荷载作用下的潜在失效模式和其在不同峰值地面加速度下重力坝的损伤破坏过程。结果表明:金安桥大坝在地震动荷载作用下,可能发生功能失效的地方多出现在坝体折坡处、碾压分区交界处、坝踵与坝基交界处、廊道顶等应力集中处。因此,加强对这些区域的抗震防护有利于提高大坝整体的抗震水平。     

考虑流固耦合效应的辽宁葠窝水库溢流坝段抗震性能分析

针对辽宁葠窝水库混凝土重力坝抗震问题,采用耦合的拉格朗日-欧拉有限元分析技术,建立了可考虑库水-坝体-基岩动力耦合效应的典型溢流坝段抗震分析数值模型。模型中,采用等效一致粘弹性边界模拟基岩的人工截断边界;采用混凝土弥散裂缝本构模型模拟混凝土的动力特性。根据烈度与地震动之间的关系,确定了水库坝体抗震设计的输入加速度峰值。据此,分析了在不同季节水位变化条件下坝体地震反应的基本特性。研究表明：完好的辽宁葠窝水库混凝土重力坝溢流坝段能满足8度的抗震设防烈度要求。地震下溢流坝段峰值位移出现在胖坝和瘦坝的坝顶迎水面位置处,胖坝的动位移较瘦坝动位移大。胖坝在闸墩与溢流堰交接处出现了拉应力最大值。有库水条件下,瘦坝峰值拉应力出现在坝趾处,无库水条件下,瘦坝最大拉应力出现在溢流堰与闸墩交接处。     

基于坝体损伤及坝基稳定的重力坝动力分析及安全评价

强震区高混凝土坝的坝体强度和动力稳定是关系大坝抗震安全最为重要的两个因素。为了全面研究地震作用下的混凝土坝的抗震安全,采用混凝土塑性损伤及动力接触模型来分析模拟地震中坝体的损伤及坝基滑裂面的破坏、张开、滑移的全过程。通过构建坝体—基岩三维有限元非线性动力接触模型综合分析震后坝体损伤区域分布、坝基滑移面的接触状态及塑性区的动态分布,避免了采用单一判据的评价的局限性。以某重力坝为例,采用超载法进行大坝动力损伤及动力稳定性进行计算并对大坝的抗震安全进行评价,得到大坝的超载安全系数。工程算例表明：该方法可以全面的评价地震过程中大坝的坝体损伤和稳定性并能够考虑其相互影响,为混凝土坝抗震安全评价提供了新的途径。     

基于能量耗散的重力坝地震响应时频特征分析

为了从能量角度研究重力坝地震响应的时频特征,在重力坝非线性动力分析基础上,探讨了重力坝地震过程中振动能量的时域耗散机制;采用小波频域多层次分解技术研究了其动响应的分频段能量特征,得到了坝体典型位置动响应分频段振动能量随高程的变化规律.通过分析发现:结构地震能量耗散为时域上不可逆的增加,坝体损伤集中出现在地震过程的某个时间段,地震动峰值后坝体损伤状态基本稳定;小波分解可以较全面地描述结构动响应能量的分频段特征.对于本文算例,在坝踵和上游折坡附近,重力坝地震响应的振动能量以4～8 Hz频段为主,这与输入的地震信号分频段特征一致;而坝顶附近则以1 ～4 Hz的振动能量为主,高频能量分量的比重随高程增大而逐渐减小.     

FRP加固钢筋混凝土圆柱破坏模式及纤维应变特性研究

大量试验验证了FRP约束混凝土圆柱能显著提高其抗震性能,但对FRP加固柱的破坏模式以及FRP应变发展规律还没有进行系统研究,而FRP加固混凝土圆柱破坏模式的预测与对其抗震性能的评估直接相关.试验表明,当FRP加固混凝土圆柱从弯剪破坏向弯曲破坏过渡时,FRP应变发展规律会发生显著变化.控制FRP有效极限应变就可以对加固柱的破坏模式进行控制,并且FRP加固柱受剪承载力的计算也和FRP有效极限应变密切相关.建议了FRP加固混凝土圆柱有效极限应变值,给出了判别FRP加固混凝土圆柱破坏模式的方法,与试验结果比较表明该判别方法简单有效.     

基于Marc二次开发实现粘弹性人工边界和振型分解反应谱法

新版《水电工程水工建筑物抗震设计规范》（NB35047-2015）中规定:"抗震设防类别为甲类的混凝土坝应考虑远域地基的辐射阻尼效应"。针对通用商业有限元软件Marc在振型分解反应谱法中的不足,且缺少时程分析法中模拟地基辐射阻尼效应的粘弹性人工边界,采用Fortran语言编制相应的独立程序及二次开发程序,以便在Mrac软件中精确实现新规范要求下的混凝土坝抗震安全评价。数值算例和工程实例分析结果验证了基于Marc二次开发实施思路和自编程序的正确性;重力坝抗震薄弱部位主要为坝体断面突变处,考虑无限地基的辐射阻尼效应后,坝体地震动力响应明显下降。     

超强地震作用下深厚覆盖层场地重力坝抗震安全研究

本文通过成层状地基地震动输入计算方法得到覆盖层边界自由场运动,采用粘弹性边界,考虑地基辐射阻尼效应及坝体和地基的接触非线性,针对强震区深厚覆盖层场地重力坝开展线性和非线性动力时程分析研究,结合需求能力比DCR评估其抗震性能。由线弹性动力时程分析可知,在运行基准地震OBE作用下,重力坝坝体应力均在允许范围内,其抗滑稳定安全系数不能满足要求;由非线性动力分析可知,在OBE和最大设计地震MDE作用下,重力坝发生较大滑动位移。通过在重力坝坝体下游坝后回填土加强重力坝抗震稳定性,结果表明,下游坝后回填土可有效减小坝体滑动位移,加强其抗震稳定性。本文针对深厚覆盖层场地重力坝开展的抗震安全研究为抗震设计提供了科学依据,为强震区深厚覆盖层场地重力坝的抗震分析提供参考。     

长期运行老化混凝土重力坝地震反应分析

早期建造的混凝土重力坝随着运行年限的增加,坝体的老化特征和损伤积累日益突出,其承载能力和抗震性能的评价问题已成为研究的重点内容。本文基于化学-湿-力耦合作用原理的连续损伤力学理论,考虑了由于力学性能退化和环境条件引起的老化因素对坝体动力损伤的影响,使用二维动力有限元-边界元混合法对丰满大坝的某溢流坝段进行了计算分析。结果表明,本文所提出的数值模型能够体现出混凝土性能的退化过程,能够预测长期运行老化混凝土重力坝的地震反应,从而为现正运行的混凝土大坝的抗震安全评价和鉴定探索了新的方法和途径。     

基于OpenSEES的FRP加固装配式梁柱节点抗震性能研究

为研究FRP加固对装配式梁柱节点及整体框架结构抗震性能的影响,本文基于OpenSEES有限元程序,建立了某装配式梁柱节点的有限元计算模型,以相关试验为基础,比较验证了所建有限元模型的可靠性。同时选用合适的FRP约束混凝土本构关系来表征FRP对混凝土性能的提升作用,设计3种装配式梁柱节点FRP加固方案,并通过有限元数值模拟,分析比较了节点承载力、滞回曲线和位移延性的差异,考察了FRP包裹层数等因素对节点承载力的影响。随后对装配式框架结构设计了3种FRP加固方式,并选取3条地震波进行结构动力时程分析以考察结构抗震性能。结果表明：FRP环向包裹加固及纵向加固能分别有效提高节点的延性能力和承载能力;FRP加固的装配式框架结构具有更好的延性及耗能能力,能有效增强结构的整体抗震性能,为装配式结构FRP加固设计提供参考。     

混凝土重力坝整体动力特性研究

结合金安桥混凝土重力坝工程的抗震性能研究,对大坝按整体模型和分缝模型分别进行了动力试验。试验中考虑了横缝和动水压力的影响,得到了整个坝体空库、满库时的空间动力特性。并对大坝进行了三维有限元动力分析,与模型试验结果进行了比较,两者符合得较好。     

Earthquake response of concrete arch dams: a plastic–damage approach

There are several alternatives to evaluate seismic damage‐cracking behavior of concrete arch dams, among which damage theory is the most popular. A more recent option introduced for this purpose is plastic–damage (PD) approach. In this study, a special finite element program coded in 3‐D space is developed on the basis of a well‐established PD model successfully applied to gravity dams in 2‐D plane stress state. The model originally proposed by Lee and Fenves in 1998 relies on isotropic damaged elasticity in combination with isotropic tensile and compressive plasticity to capture inelastic behaviors of concrete in cyclic or dynamic loadings. The present implementation is based on the rate‐dependent version of the model, including large crack opening/closing possibilities. Moreover, with utilizing the Hilber–Hughes–Taylor time integration scheme, an incremental–iterative solution strategy is detailed for the coupled dam–reservoir equations while the damage–dependent damping stress is included. The program is initially validated, and then, it is employed for the main analyses of the Koyna gravity dam in a 3‐D modeling as well as a typical concrete arch dam. The former is a major verification for the further examination on the arch dam. The application of the PD model to an arch dam is more challenging because the governing stress condition is multiaxial, causing shear damage to become more important than uniaxial states dominated in gravity dams. In fact, the softening and strength loss in compression for the damaged regions under multiaxial cyclic loadings affect its seismic safety. Copyright © 2013 John Wiley & Sons, Ltd.     

考虑劣化屈服老化裂纹后混凝土水库堤坝排水边坡抗震性研究

针对在水库堤坝排水边坡混凝土裂纹的抗震性研究中,未考虑岩土体抗剪强度参数的劣化屈服效应以及混凝土裂纹的老化,存在抗震性判断结果准确率较差等问题,提出水库堤坝排水边坡混凝土考虑老化后产生裂纹的抗震性能研究方法。模拟强震下边坡混凝土的开裂破坏过程,根据D-P屈服准则,实现对闸墩混凝土材料的屈服判断。采用薄层整体单元模拟和分离式裂纹单元,实现混凝土裂纹的数值模拟,加载地震波后,获取混凝土裂纹的强震响应规律与破坏特征。实验结果可知,本文方法对坝体位移变化的研究精度高,得到的混凝土裂纹扩展范围更为准。运用本文方法对水库堤坝排水边坡混凝土的抗震性研究准确率以及可信度较高,说明本文方法具有一定的可取性。     

Seismic failure modeling of concrete dams considering heterogeneity of concrete

Study on the failure process of high concrete dams subjected to strong earthquakes is crucial to reasonable evaluation of their seismic safety. Numerical simulation in this aspect involves dynamic failure analysis of big bulk concrete dam subjected to cyclic loading. The Rock Failure Process Analysis (RFPA) proposed by C.A. Tang, with successful applications to failure modeling of rock and concrete specimens mainly subjected to static loading, is extended for this purpose. For using the proposed model, no knowledge on the cracking route needs to be known beforehand, and no remeshing is required. Simulation of the whole process of elastic deformation, initiation and propagation of microcracks, severe damage and ultimate failure of concrete dams in earthquakes with a unified model is enabled. The model is verified through a shaking table test of an arch dam. Finally a practical gravity dam is employed as a numerical example. Considering the uncertainty in ground motion input and concrete material, typical failure process and failure modes of gravity dam are presented. Several small cracks may occur due to tension particularly at dam neck, dam faces and dam heel, and a few of them evolve into dominant ones. Relatively smaller earthquake may cause damage to the dam neck while a bigger one may bring on cracks at lower parts of the dams. Cracking at the dam bottom may incline to a direction almost perpendicular to the downstream face after propagating horizontally for a certain distance when the shaking is strong enough.     

Seismic failure modeling of concrete dams considering heterogeneity of concrete

Study on the failure process of high concrete dams subjected to strong earthquakes is crucial to reasonable evaluation of their seismic safety. Numerical simulation in this aspect involves dynamic failure analysis of big bulk concrete dam subjected to cyclic loading. The Rock Failure Process Analysis (RFPA) proposed by C.A. Tang, with successful applications to failure modeling of rock and concrete specimens mainly subjected to static loading, is extended for this purpose. For using the proposed model, no knowledge on the cracking route needs to be known beforehand, and no remeshing is required. Simulation of the whole process of elastic deformation, initiation and propagation of microcracks, severe damage and ultimate failure of concrete dams in earthquakes with a unified model is enabled. The model is verified through a shaking table test of an arch dam. Finally a practical gravity dam is employed as a numerical example. Considering the uncertainty in ground motion input and concrete material, typical failure process and failure modes of gravity dam are presented. Several small cracks may occur due to tension particularly at dam neck, dam faces and dam heel, and a few of them evolve into dominant ones. Relatively smaller earthquake may cause damage to the dam neck while a bigger one may bring on cracks at lower parts of the dams. Cracking at the dam bottom may incline to a direction almost perpendicular to the downstream face after propagating horizontally for a certain distance when the shaking is strong enough.     

Seismic performance of masonry walls retrofitted with steel reinforced grout

An innovative solution for the seismic protection of existing masonry structures is proposed and investigated through shake table tests on a natural scale wall assemblage. After a former test series carried out without reinforcement, the specimen was retrofitted using Steel Reinforced Grout. The strengthening system comprises horizontal strips of ultra‐high strength steel cords, externally bonded to the masonry with hydraulic lime mortar, and connectors to transversal walls, applied within the thickness of the plaster layer. In order to assess the seismic performance of the retrofitted wall, natural accelerograms were applied with increasing intensity up to failure. Test results provide a deep understanding of the effectiveness of mortar‐based composites for improving the out‐of‐plane seismic capacity of masonry walls, in comparison with traditional reinforcements with steel tie‐bars. The structural implications of the proposed solution in terms of dynamic properties and damage development under earthquake loads are also discussed.Copyright © 2015 John Wiley & Sons, Ltd.     

高强钢筋高延性纤维增强混凝土框架结构的屈服机制和抗震性能

为了对混凝土框架结构的地震破坏机制和抗震性能进行控制,在框架柱中配置高强钢筋,并将纤维增强混凝土(FRC)用于框架结构的预期损伤部位。结构柱中的高强钢筋用来减小结构的残余变形,FRC材料用来增加结构的耗能能力和损伤容限。设计了三个框架,采用动力弹塑性时程分析方法进行分析。研究结果表明,采用高强钢筋提高了结构的整体承载能力,在层间侧移角达到3%之前避免了柱铰的出现(包括底层柱底),并且减小了结构的残余变形;预期损伤部位采用FRC材料能够提高结构的塑性耗能。     

Experimental seismic investigation of Sefid‐rud concrete buttress dam model on shaking table

Owing to the devastating M7.6 earthquake of 20 June 1990 that occurred in the northern province of Iran, Sefid‐rud concrete buttress dam located near the epicenter was severely shaken. The crack penetrated throughout the dam thickness near slope discontinuity, causing severe leakage, but with no general failure. In this study, nonlinear seismic response of the highest monolith with empty reservoir is investigated experimentally through model testing. A geometric‐scaled model of 1:30 was tested on a shaking table with high‐frequency capability to study dynamic cracking of the model and serve as data for nonlinear computer model calibration. Three construction joints are set up in the model to simulate effects of construction aspects. The experimental results are then compared with smeared crack and damage mechanics finite‐element simulations using nonlinear concrete constitutive models based on fracture mechanics. The crack patterns obtained from numerical models are in good agreement with those obtained from shaking table tests for the case of including construction joint effects and rigid foundation. Copyright © 2008 John Wiley & Sons, Ltd.     

Experimental investigation of damage behavior of RC frame members including non-seismically designed columns

Reinforced concrete (RC) frame structures are one of the mostly common used structural systems, and their seismic performance is largely determined by the performance of columns and beams. This paper describes horizontal cyclic loading tests often column and three beam specimens, some of which were designed according to the current seismic design code and others were designed according to the early non-seismic Chinese design code, aiming at reporting the behavior of the damaged or collapsed RC frame strctures observed during the Wenchuan earthquake. The effects of axial load ratio,shear span ratio, and transverse and longitudinal reinforcement ratio on hysteresis behavior, ductility and damage progress were incorporated in the experimental study. Test results indicate that the non-seismically designed columns show premature shear failure, and yield larger maximum residual crack widths and more concrete spalling than the seismically designed columns. In addition, longitudinal steel reinforcement rebars were severely buckled. The axial load ratio and shear span ratio proved to be the most important factors affecting the ductility, crack opening width and closing ability, while the longitudinal reinforcement ratio had only a minor effect on column ductility, but exhibited more influence on beam ductility. Finally, the transverse reinforcement ratio did not influence the maximum residual crack width and closing ability of the seismically designed columns.     

基于抗震承载力和改进能力谱法的钢筋混凝土结构耐久性设计

钢筋混凝土结构是一种广泛使用的结构形式,其耐久性设计是一个十分迫切需要解决的问题。在一般大气环境下,混凝土碳化和钢筋锈蚀是钢筋混凝土结构耐久性的重要影响因素,在其作用下结构的抗震承载力发生变化,因此可将结构抗震承载力因素引入结构的耐久性设计中。采用改进能力谱法,以罕遇地震下薄弱层的弹塑性层间位移作为结构承载力指标,研究了一般大气环境下钢筋锈蚀因素对钢筋混凝土结构抗震耐久性的影响,提出了基于抗震承载力和改进的能力谱法的钢筋混凝土结构耐久性设计方法。通过一个五层钢筋混凝土结构的算例说明了验算结构抗震性能耐久行的必要性。     

Numerical simulation of reinforcement strengthening for high‐arch dams to resist strong earthquakes

This paper focuses on analyzing the nonlinear seismic response of high‐arch dams with cantilever reinforcement strengthening. A modified embedded‐steel model is presented to evaluate the effects of the strengthening measure on alleviating the extension and opening of cracks under strong earthquakes. By stiffening reinforced steel, this model can easily consider the steel–concrete interaction for lightly reinforced concrete (RC) members without the need of dividing them into RC and plain concrete zones. The new tensile constitutive relations of reinforced steel are derived from the load–deformation relationship of RC members in direct tension. This model has been implemented in the finite element code and its applicability is verified by two numerical simulations for RC tests. Subsequently, numerical analyses for a 210‐m high‐arch dam (Dagangshan arch dam) are conducted with and without the presence of cantilever reinforcement. Numerical results show that reinforcement strengthening can reduce the nonlinear response of the arch dam, e.g. joint opening and crest displacement, and limit the extension and opening width of concrete cracks. Copyright © 2008 John Wiley & Sons, Ltd.