钢筋混凝土柱低周疲劳性能的试验研究

结构的地震破坏可看作是超过屈服后的非弹性阶段的低周疲劳问题,而单根柱的破坏分析是整个框架失效分析的基础,本文通过八根１／２比例的钢筋混凝土柱在不同位移幅值下的等幅低周疲劳试验和六根非对称位移循环下低疫疲劳试验,探讨了在不同位移幅值下降筋混凝土柱累积损伤的发展规划以及低周疲劳寿命的表达式,给出了低周疲劳寿命不同位移水平下正负位移幅值比之间关系的表达式。希望以此为基础,建立更为合理的结构抗震破坏准则。     

基于剩余寿命等效的钢筋混凝土构件地震损伤模型

基于剩余寿命等效的概念，提出了钢筋混凝土构件地震损伤改进模型。其基本思想是认为以某损伤参数(如刚度、位移延性、能量等)建构的损伤指数与疲劳损伤指数(如纵筋累积疲劳损伤)，在损伤指数D＝1．0条件下都可以表示构件失效。这样在某时刻以不同损伤指数表达的构件剩余寿命(1．0—Di)与损伤指数增量ΔDi之比，都等于使构件完全失效时对应的继续循环加载周数。利用这种等效关系定义了新的损伤指数，可以在构件的反应参量和破坏机理之间建立起联系。作为实际应用给出了一种基于截面刚度退化的低周反复荷载作用下钢筋混凝土桥墩损伤模型。     

强震持时对钢筋混凝土结构地震累积破坏的影响

本文在计算模型中考虑了钢筋混凝土结构的低周疲劳性能,建立了一种以退化刚度比作为破坏参数的地震破坏评估模型,此模型不仅能够反映大变形破坏,而且也能反映累积损伤效应。在此基础上,文中还研究了强震持时对钢筋混凝土结构累积破坏的影响。结果表明:对于中强长持时地震,低周疲劳效应十分明显地增大了结构的破坏程度,而且强震动持时对结构的累积破坏与结构的非线性变形的低周疲劳效应关系密切。     

基于轴向位移的钢支撑疲劳损伤评估方法

在罕遇地震下,框架-中心支撑结构中的钢支撑常因局部屈曲位置的低周疲劳开裂而过早退出工作。本文在焊接工字形钢支撑低周疲劳试验研究基础上,提出了一种可用于框架-中心支撑体系非线性动力时程分析中钢支撑疲劳损伤评估的经验方法,并给出了相关步骤的算法流程。研究结果表明:本文方法以钢支撑轴向位移为损伤参量,能实时估算在随机位移荷载下钢支撑的低周疲劳累积损伤发展,并与试验结果吻合较好。     

循环荷载特征对焊接工字形钢支撑低周疲劳性能的影响

通过14根铰支焊接工字形支撑在不同特征的循环轴向位移荷载下的低周疲劳试验，研究了循环轴向位移荷载的位移幅值、平均位移幅值及加载次序等因素对钢支撑低周疲劳及耗能性能的影响。研究发现，对称循环荷载中幅值越小，支撑翼缘局部屈曲发展越晚，其耗能及承载力退化也越平缓。文中提出了支撑在幅值6δ≤Δδ≤12δy的对称循环荷载下的疲劳寿命经验公式。试验表明，循环荷载的位移幅值是支撑疲劳损伤及耗能退化的最主要影响因素，过载峰效应及适当的平均压位移幅值改善了钢支撑低周疲劳及耗能性能。     

考虑材料损伤累积的型钢高强混凝土框架节点数值建模及参数分析

为研究地震作用下损伤累积对型钢高强混凝土框架节点抗震性能的影响,基于5榀型钢高强混凝土框架节点低周反复加载试验结果,分析节点构件损伤累积过程及其对刚度和强度的影响。从材料自身损伤入手,通过引入刚度影响系数考虑循环荷载作用下混凝土的单边效应,对Faria-Oliver本构模型进行改进,进而建立适应于型钢混凝土结构的材料损伤累积本构模型。同时基于该模型采用ANSYS分析软件对地震作用下的型钢高强混凝土框架节点进行数值分析,并与试验结果进行对比分析。结果表明:采用本文建立的材料损伤累积本构模型能较好地反映地震作用下型钢高强混凝土框架节点的损伤特性。在此基础上,进一步分析构件轴压比、配箍率、配钢率等设计参数对型钢高强混凝土框架节点抗震性能的影响。研究成果可为该类结构构件的抗震设计提供理论和技术支撑。     

RC梁与柱在不同地震作用下的变形限值分析

分析钢筋混凝土(RC)梁与柱基于不同地震作用下的变形限值,对钢筋混凝土梁与柱进行低周往复循环加载拟静力试验。然后对试验进行仿真模拟,将试验结果与仿真模拟结果进行对比分析,发现二者结果相近,从而验证仿真模拟的可行性。在构件的荷载-位移曲线上获取屈服点、峰值点和极限点,分别计算这3个状态点对应的侧向位移值与构件计算长度的比值,则可得出构件在小震、中震和大震时对应的位移角值。改变梁、柱构件的剪跨比、配筋形式以及柱构件的轴压比等,来得到更多构件的荷载-位移曲线,将所有结果进行统计分析,得到钢筋混凝土构件在不同地震作用下的位移角限值。     

基于界面疲劳理论的钢筋混凝土腐蚀疲劳破坏研究

腐蚀疲劳是钢筋混凝土结构破坏的主要因素之一.基于剪切筒模型及文中选用的实验加载方式,考虑界面摩擦系数的衰减,同时考虑力学因素-应力比R和加载频率f的影响,研究了钢筋与混凝土界面腐蚀疲劳裂纹扩展情况.通过对Paris公式的修正,借助能量耗散率给出腐蚀疲劳数学模型,得到了界面腐蚀疲劳脱粘速率,脱粘长度与循环荷载作用次数的关系.同时考虑混凝土损伤(如刚度衰减)的影响,分析了影响界面腐蚀疲劳(CF)裂纹扩展速率的因素,如应力比,加载频率.     

考虑结构低周疲劳特性的地震反应谱

本文将钢筋混凝土框架和钢框架的低周疲劳性能引入地震反应谱的计算中,以地震反应累积损伤系数的形式考察了结构低周疲劳性能对地震破坏反应的影响。分析结果表明:1.结构破坏同时受结构本身强度及地震强烈强度的影响,普通结构在地震作用下有所损伤是难免的,但并不一定导致完全丧失抵抗外荷载能力的那种倒塌;2.结构强度和结构周期是引起地震作用下结构破坏的主要因素,当这两者均为中等大小时,结构低周疲劳性能及地震动持续时间也会对结构破坏产生影响;3.地震动持续时间对结构物损伤的影响受结构低周疲劳性能决定,它随结构本身的性质,尤其是结构寿命曲线而有差异。     

反复荷载作用下矩形钢管混凝土树状节点的非线性分析

本文在确定了往复应力作用下钢管混凝土的钢材和核心混凝土的应力-应变关系的基础上,利用纤维杆元模型,有限元模型对钢管混凝土Y形柱和十字形钢梁连接的节点的荷载-位移滞回关系曲线及其骨架曲线进行了计算,并与试验结果进行了比较。结果表明：由纤维杆元模型与试验所得的低周反复荷载作用下的骨架曲线极为相似,但在峰值荷载后差异较大;由纤维杆元模型和有限元所得的在低周反复荷载作用下滞回曲线也与在反复荷载作用下试验所得的结果相一致。纤维杆元模型能准确地预测节点的弹塑性行为和整体抗震性能,可用于节点滞回性能的非线性参数分析研究。在此基础上研究了方钢管混凝土柱的轴压比,宽厚比及核心混凝土强度对节点受力性能的影响。     

钢筋混凝土框架柱震损程度量化鉴定方法

钢筋混凝土结构震后损伤鉴定中,最常见的方式是鉴定者观察房屋破坏现象,根据经验给出震损等级。该方法直观高效,但对鉴定者的专业经验要求较高,且鉴定结果的主观差异较大。对此以RC框架柱为对象,开展了基于震损现象的震损量化鉴定方法研究:在RC框架柱震损现象量化试验基础上给出基于构件骨架曲线特征阶段的震损分级方法;对7个RC框架柱试件进行了改进Park-Ang损伤指数分析,建立了RC框架柱损伤指数-震损分级-震损现象的对应关系;基于RC框架柱的试验结果及典型震害编制了RC框架柱震损图集,并给出了使用图集进行框架柱震损鉴定的流程及方法。使用该方法对2个实际震害中的RC框架柱进行了震损鉴定,可为更加客观以及准确地开展钢筋混凝土结构的震损鉴定提供参考。     

板钉连接CFST柱-RC梁节点梁端塑性铰区受力性能数值模拟

建立竖板-栓钉连接钢管混凝土（CFST）柱-钢筋混凝土（RC）梁节点试件（SSJD）拟静力加载试验有限元模型,并在节点损伤情况、梁端荷载-位移曲线等数值模拟结果与试验结果吻合较好的基础上,进一步开展了RC梁混凝土强度、配筋率ρ_s和连接竖板长度L_b及界面连接情况等对CFST柱-RC梁节点梁端塑性铰区域力学性能的影响。研究结果表明,RC梁混凝土强度对试件SSJD塑性铰区域受力性能的影响较小;适筋范围内RC梁配筋率增加可适当提高试件SSJD承载力和延性;随着连接竖板长度的增加,梁端塑性铰区域外移,梁破坏荷载增大;本研究给出的RC梁与CFST柱之间的界面抗剪承载力模拟值与计算值吻合较好,可用于界面抗剪设计。     

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.     

Cyclic Displacement Model for Reinforced Concrete Columns

Reinforced concrete (RC) structures in low to moderate seismic regions and many older RC structures in high seismic regions include columns with steel reinforcement details not meeting the requirements of modern seismic design codes. These columns typically fail in shear or in a brittle manner and their behavior must be accurately captured when RC structures are modeled and analyzed. The total lateral displacement of a low ductility or shear critical RC column can be represented as the sum of three displacement components: (1) flexural displacement, (2) displacement due to slippage of the reinforcing bars at column ends, and (3) shear displacement. In this study, these three displacement components are separately modeled and then combined together following a proposed procedure based on the expected overall behavior of the column and its failure mechanism. A simplified slip model is proposed. The main objective of this research is to develop an easy-to-apply method to model and capture the cyclic behavior of RC columns considering the shear failure mechanism. The proposed model is validated using the available data from RC column and frame experiments.     

Composed analytical models for seismic assessment of reinforced concrete bridge columns

This paper presents general composed analytical models to predict the behavior of reinforced concrete (RC) bridge columns. The analytical models were developed in OpenSees to represent the common hysteretic behavior of RC bridge columns. The proposed composed models can accommodate flexure failure, flexure‐shear failure, and pure shear failure, which are observed in existing RC bridge piers. The accuracy of the models was verified using data from the static cyclic‐loading experiments of 16 single columns and one multi‐column bent and dynamical experiment from two pseudo‐dynamic tests. The results showed that the analytical models could simulate the nonlinear behavior until the post‐failure behavior, including the strength degradation, the buckling of the reinforcement, and the pinching effect. Therefore, a global view of the behavior of reinforcement concrete is prescribed as simply as possible from the academic perspective, and these models are expected to provide sufficient accuracy when applied in engineering practice. Copyright © 2014 John Wiley & Sons, Ltd.     

地震作用下钢筋混凝土柱变形与损伤研究

为量化地震作用下钢筋混凝土（RC）柱损伤情况和变形,并将不同地震破坏状态下RC柱损伤和变形进行分析。从太平洋地震工程研究中心（PEER）数据库中收集91组RC柱抗震试验数据,选取4种广泛应用的构件损伤模型进行计算,将损伤发展曲线与层间位移角发展曲线进行对比分析。对RC柱损伤指标限值进行归一化处理,统计分析后得到不同破坏等级下的位移角限值,并给出了RC柱各破坏等级下的位移角限值与损伤指标限值对应关系。研究结果表明,牛荻涛损伤模型可更准确地评价地震作用下结构构件损伤程度,且与层间位移角发展曲线均呈近似线性增长趋势;不同破坏等级下的位移角限值验算保证率均＞80%,表明本文提出的位移角限值具有一定合理性。     

Seismic behavior and strength capacity of steel tube‐reinforced concrete composite columns

The steel tube‐reinforced concrete (ST‐RC) composite column is a novel type of composite column, which consists of a steel tube embedded in RC. In this paper, the seismic behavior of ST‐RC columns is examined through a series of experiments in which 10 one‐third scale column specimens were subjected to axial forces and lateral cyclic loading. The test variables include the axial force ratio applied to the columns and the amount of transverse reinforcement. All specimens failed in a flexural mode, showing stable hysteresis loops. Thanks to the steel tube and the high‐strength concrete it is filled with, the ST‐RC column specimens had approximately 30% lower axial force ratios and 22% higher maximum bending moments relative to the comparable RC columns when subjected to identical axial compressive loads. The amount of transverse reinforcement made only a small difference to the lateral load‐carrying capacity but significantly affected the deformation and energy dissipation capacity of the ST‐RC columns. The specimens that satisfied the requirements for transverse reinforcement adopted for medium ductile RC columns as specified by the Chinese Code for Seismic Design of Buildings (GB 50011‐2010) and EuroCode 8 achieved an ultimate drift ratio of around 0.03 and a displacement ductility ratio of approximately 5. The design formulas used to evaluate the strength capacity of the ST‐RC columns were developed on the basis of the superposition method. The predictions from the formulas showed good agreement with the test results, with errors no greater than 10%. Copyright © 2013 John Wiley & Sons, Ltd.