Pushover analysis of reinforced concrete frames considering shear failure at beam-column joints

Since most current seismic capacity evaluations of reinforced concrete （RC） frame structures are implemented by either static pushover analysis （PA） or dynamic time history analysis, with diverse settings of the plastic hinges （PHs） on such main structural components as columns, beams and walls, the complex behavior of shear failure at beam-column joints （BCJs） during major earthquakes is commonly neglected. This study proposes new nonlinear PA procedures that consider shear failure at BCJs and seek to assess the actual damage to RC structures. Based on the specifications of FEMA-356, a simplified joint model composed of two nonlinear cross struts placed diagonally over the location of the plastic hinge is established, allowing a sophisticated PA to be performed. To verify the validity of this method, the analytical results for the capacity curves and the failure mechanism derived from three different full-size RC frames are compared with the experimental measurements. By considering shear failure at BCJs, the proposed nonlinear analytical procedures can be used to estimate the structural behavior of RC frames, including seismic capacity and the progressive failure sequence of joints, in a precise and effective manner.

Predetermination of potential plastic hinges on reinforced concrete frames using GFRP reinforcement

In the past,glass fiber-reinforced polymer(GFRP)-reinforcement has been successfully applied in reinforced concrete(RC)structures where corrosion resistance,electromagnetic neutrality,or cuttability were required.Previous investigations suggest that the application of GFRP in RC structures could be advantageous in areas with seismic activity due to their high deformability and strength.However,especially the low modulus of elasticity of GFRP limited its wide application as GFRP-reinforced members usually exhibit considerably larger deformations under service loads than comparable steel-reinforced elements.To overcome the aforementioned issues,the combination of steel and GFRP reinforcement in hybrid RC sections has been investigated in the past.Based on this idea,this paper presents a novel concept for the predetermination of potential plastic hinges in RC frames using GFRP reinforcement.To analyze the efficiency of the concept,nonlinear finite element simulations were performed.The results underscore the high efficiency of hybrid steel-GFRP RC sections for predetermining potential plastic hinges on RC frames.The results also indicate that the overall seismic behavior of RC structures could be improved by means of GFRP as both the column base shear force during the seismic activity as well as the plastic deformations after the earthquake were considerably less pronounced than in the steel-reinforced reference structure.

Achievements of Truss Models for Reinforced Concrete Structures

Achievements are presented for truss models of RC structures developed in previous years: 1. Two constitutive models, biaxial and triaxial, are based on regular trusses, with bars obeying nonlinear uniaxial σ-ε laws of material under simulation;both models have been compared with test results and show a dependence of Poisson ratio on curvature of σ-ε law. 2. A truss finite element has been used in the nonlinear static and dynamic analysis of plane RC frames;it has been compared with test results and describes, in a simple way, the formation of plastic hinges. 3. Thanks to the very simple geometry of a truss, the equilibrium equations can be easily written and the stiffness matrix can be easily updated, both with respect to the deformed truss, within each step of a static incremental loading or within each time step of a dynamic analysis, so that to take into account geometric nonlinearities. So the confinement of a RC column is interpreted as a structural stability effect of concrete. And a significant role of the transverse reinforcement is revealed, that of preventing, by its close spacing and sufficient amount, the buckling of inner longitudinal concrete struts, which would lead to a global instability of the RC column. 4. The proposed truss model is statically indeterminate, so it exhibits some features, which are not met by the “strut-and-tie” model.

Mechanism of improving ductility of high strength concrete T-section beam confined by CFRP sheet subjected to flexural loading

For the purpose of inventing a new seismic retrofitting method for the reinforced high strength concrete （HSC） T-section beam using carbon fiber reinforced polymer （CFRP） sheet, three series, a total of twelve T-section beams with nine specimens confined by CFRP sheet in the plastic zone and three control beams were conducted up to failure under four-point bending test. The effectiveness of confining CFRP sheet on improving the flexural ductility of tmstrengthened T-section beams was studied. The parameters such as the width and the thickness of CFRP sheet and the type of T-section were analyzed. The experimental results show that ductility and rotation capacity of plastic hinge can be improved by the confinement of CFRP sheet, and the ductility indices increase with the increment of width and thickness of CFRP sheet. A plastic rotation model considering the width of CFRP sheet and the effect of flange of T-section beam is proposed on the basis of the model of BAKER, and the test results show a good agreement with the perdicted results. The relevant construction suggestions for seismic retrofitting design of beam-slabs system in cast-in-place framework structure are presented.

加强型翼缘-波纹腹板组合隔板贯通式节点抗震性能研究

为克服隔板贯通式节点易发生脆性断裂而导致结构破坏的不足,结合“加强”和“削弱”的措施,使塑性铰外移,提出了加强型翼缘-波纹腹板组合隔板贯通式梁柱新型节点,并利用有限元软件ABAQUS探究了该新型节点在低周往复荷载作用下的破坏模式、应力分布情况。研究波纹数量、波纹厚度、加强板厚度、加强板长度这4种参数对该新型节点的滞回曲线、骨架曲线、耗能能力的影响规律。结果表明:新型节点有较好的承载力,应力主要集中在梁翼缘上波纹腹板削弱处,破坏发生在远离削弱处一侧,且腹板未发生屈曲变形。随着波纹厚度、加强板长度的增大,新型节点的承载力增加,耗能能力下降;随着波纹数量的增多,新型节点承载力和耗能能力增加;随着加强板厚度的增大,承载力增加,耗能能力先减小后增大。

钢筋混凝土薄壁空心高墩塑性铰长度计算方法

针对我国现行抗震设计规范尚未明确给出钢筋混凝土(RC)薄壁空心高墩塑性铰长度计算方法的问题,首先收集整理了既有RC桥墩塑性铰长度计算方法以及试验数据,分析影响塑性铰计算长度的主要因素;同时对实际桥梁工程采用的RC薄壁空心墩构造参数进行统计归纳.在验证有限元建模方法准确性后,采用ABAQUS软件建立了高度为40~120 m的8种典型RC薄壁空心高墩的精细化有限元模型,并开展非线性推覆分析,得到不同高度桥墩的等效塑性铰长度.最后讨论不同塑性铰长度计算方法的适用性,发现Eurocode 8规范的计算公式精度最高,可用于计算RC薄壁空心高墩的塑性铰长度.

塑性铰区加强方式对高强混凝土剪力墙抗震性能的影响

为研究塑性铰区加强方式对高强混凝土剪力墙抗震性能的影响,首先,开展4片高强钢筋高强混凝土剪力墙的低周反复荷载试验与ABAQUS有限元模拟;其次,分析塑性铰区采用添加钢纤维、加密箍筋、外包钢板3种加强方式对剪力墙破坏形态、滞回特性、承载力与变形能力、强度与刚度退化、耗能能力以及塑性铰发展长度等方面的影响机理;最后,提出适用于高强钢筋高强混凝土剪力墙的等效塑性铰长度与承载力计算方法。研究结果表明:3种加强方式均有利于减轻墙体损伤程度,降低剪切变形占比,提高变形与耗能能力;当3种方式加强段高度相同时,添加钢纤维的方式对墙体破坏形态作用最明显;墙底部外包合理厚度的钢板可以使墙体塑性铰充分发展,形成双塑性铰区,从而使试件峰值荷载提高17.7%、极限位移角提高75.0%。基于简化的曲率分布与塑性变形基本假定,考虑力的平衡关系、弯曲与剪切变形的协调关系,本文提出的等效塑性铰长度计算方法与水平承载力计算方法精度较高。

基于静力试验的柱端铰型受控摇摆钢筋混凝土框架地震响应数值分析

柱端铰型受控摇摆钢筋混凝土框架(CR-RCFC)是一种新型的可恢复功能结构,通过摇摆节点的构造来“弱化”结构整体抗侧刚度,从而达到减小地震响应的目的。CR-RCFC结构在振动台试验中呈现了在中震和大震作用下“主体构件免损伤,耗能构件易更换”的韧性抗震效果。振动台试验后进行低周反复静载试验得到拆除阻尼器后的CR-RCFC结构柱铰节点弯矩-转角滞回曲线和转动刚度等抗震性能参数。利用静力试验得到的结构抗震性能参数进行结构地震响应数值模拟,将数值模拟结果与振动台试验结果进行对比分析。对比分析结果表明:通过静力试验数据可以精确得到CR-RCFC结构节点抗震性能参数,根据该抗震性能参数进行的数值模拟结果与振动台试验结果吻合较好。

爆后钢筋骨架零长度塑性铰失稳判别模型与试验验证

为了进一步研究骨架的残余承载能力对建(构)筑物失稳倒塌的影响,基于爆破后立柱钢筋骨架形态及其受力情况,建立了零长度塑性铰计算模型,并开展了不同爆破破坏程度下残余钢筋骨架的承载能力测试试验。结果表明:高度和弯曲程度对承重立柱爆后钢筋骨架承载能力有显著影响,当初始挠度接近时,试件峰值承载力随骨架高度增加呈线性降低关系;当骨架高度相同时,试件峰值承载力随弯曲程度增加呈非线性降低关系;与传统欧拉等直压杆模型和初弯曲压杆模型相比,零长度塑性铰失稳判别模型的计算结果更接近模型试验值。论文研究成果对高大建(构)筑物拆除爆破设计和抗连续倒塌分析具有一定参考意义。

现浇钢筋混凝土框架结构节点施工质量控制分析

随着社会经济的不断发展,我国建筑工程数量逐渐增多,框架结构作为建筑工程的重要部分,对于保障建筑质量具有重要意义。而在现浇钢筋混凝土框架结构中,节点属于施工重要位置,能够起到承受板、柱、梁的作用,节点施工质量对于整体结构的稳定性、安全性和耐久性具有重要影响。然而,由于多种因素的影响,节点施工质量控制存在一定的难度。基于此,本文主要结合具体工程案例,分析现浇钢筋混凝土框架结构在节点施工质量控制方面的不足与控制要点,以期保证梁柱节点的施工质量,促进建筑行业的长久以及稳定发展。

预应力加强框架节点的抗震性能研究综述

通过总结国内外预应力加强框架节点的实验及数值模拟研究,分析了不同加强形式对框架节点的影响,结果表明:预应力加强节点与传统节点相比具有更好的承载力及抗剪强度,能提升结构的抗震性能。最后,对预应力加强框架节点研究进行了总结与展望。

基于纤维梁柱单元的墩柱弹塑性性能数值分析模型

基于OpenSees开源平台,采用基于位移的纤维梁柱单元和零长度单元,建立了考虑钢筋混凝土墩柱塑性弯曲变形和粘结滑移效应的滞回推覆(Pushover)分析有限元模型,分析了塑性铰区单元长度对墩柱弹塑性性能数值模拟结果的影响,探讨了单元长度的合理取值,最后,基于美国PEER结构试验数据库中3个弯曲破坏的钢筋混凝土悬臂墩的拟静力试验结果,验证了数值模型的正确性。结果表明:采用基于位移的梁柱单元模拟钢筋混凝土墩柱弹塑性性能时,塑性铰区单元长度对其最大水平抗力和位移延性都有显著的影响;合理单元长度为等效塑性铰长度,而等效塑性铰长度可以采用Priestley等提出的经验公式计算。

型钢剪力架增强混凝土板柱节点抗冲切试验研究

研究型钢剪力架增强钢筋混凝土板柱节点的抗冲切性能,得到型钢剪力架设计的优化方案。考虑型钢的翼缘厚度、腹板厚度、伸臂长度、锚固栓钉规格不同,设计9个板柱节点试件进行反向静力模拟加载试验,考察试件的破坏历程和破坏形态,量测节点的承载力、变形和应变等指标,调查不同设计组合对板柱节点抗冲切破坏模式和承载力的影响规律,阐明其失效破坏机制。结果表明:型钢剪力架能够提高板柱节点的抗冲切性能,改善冲切破坏的脆性特点;设置型钢翼缘、锚固栓钉能够强化节点内纵筋、型钢和混凝土的协同工作,增加型钢腹板厚度和设置翼缘均可在一定程度上提高板柱节点的抗冲切承载力和延性能力;锚固栓钉代替型钢翼缘可改善板柱节点的抗冲切承载力,但在改善延性方面的效果不如带翼缘试件;增加翼缘厚度来提升承载力存在边际效应,型钢伸臂长度太短难以发挥型钢剪力架的抗冲切增强作用。参考现有规范方法以及试验结果,提出了型钢剪力架增强混凝土板柱节点抗冲切承载力计算方法。

临沂金水湾二期超高层结构设计

临沂金水湾二期超高层项目结构高度153.3m,属于高震区超高层超限结构,地上结构采用钢管混凝土框架⁃钢筋混凝土核心筒混合结构,塔楼外框柱均倾斜布置以满足建筑外立面的变化。采用YJK和ETABS两种软件对主塔楼结构进行了弹性分析,并采用PERFORM⁃3D软件进行了动力弹塑性分析。从结构体系、性能设计等方面对超高层结构设计进行了简要论述,并对梭形超高层建筑的斜柱设计要点、环带桁架、底层分叉柱以及结构动力弹塑性四个方面进行了详细分析、介绍,最后给出了上述要点的计算结论和构造建议。

新型装配式转动摩擦型梁柱十字耗能节点拟静力试验研究

为提高装配式钢筋混凝土梁柱节点的耗能能力,提出了一种新型梁端转动摩擦耗能器RFED(new Beam-end Rotational Friction Energy Dissipation Device,RFED)。选取钢筋混凝土梁柱十字节点为研究对象,对4个采用不同摩擦片的新型装配式摩擦型往复弯曲耗能节点JD1~JD4进行拟静力逐级加载试验与疲劳性能试验。试验结果说明:①RFED能够通过一定程度的反复转动耗能保护预制梁、柱;②JD2、JD3、JD4滞回曲线均表现为饱满的平行四边形,耗能能力强,JD1耗能能力相对较低,且疲劳试验中承载力衰减程度过大;③JD2滑移荷载不能保持稳定;JD4起滑荷载最大达到滑移荷载的2倍左右,不利于准确控制承载力;而JD3耗能能力强、起滑荷载及滑动荷载稳定。因此,JD3所使用的H62黄铜片且钢材表面喷涂无机富锌漆的摩擦面,最适宜于工程应用。

柱增强系数取值对钢筋混凝土抗震框架塑性铰机构的控制效果

以我国《混凝土结构设计规范》规定的8 度区二级抗震等级平面框架为例,采用大小不同的柱弯矩增强系数进行框架设计,利用杆系非弹性动力反应分析程序PL-AFJD 对这些框架进行多波输入下的地震反应分析,识别柱弯矩增强系数取值对框架在强震下形成的塑性铰机构的控制效果,并分析达到不同控制效果的主要原因。研究结果对我国结构设计规范优化柱弯矩增强系数取值有一定参考价值。

钢骨高强混凝土框架节点恢复力模型的研究

为了研究钢骨高强混凝土框架节点的抗震性能,对五个钢骨高强混凝土框架节点进行了低周反复荷载作用下受力性能的试验研究.在试验研究基础上,考虑了节点配箍率、含钢率和轴压比,对节点延性、耗能和强度、刚度退化等影响,建立了钢骨高强混凝土框架节点的恢复力模型.

钢筋混凝土梁塑性铰长度变化规律及尺寸效应

为了研究钢筋混凝土梁塑性铰长度随荷载的变化规律及其尺寸效应,依据15根不同截面尺寸的钢筋混凝土梁单调和低周往复加载试验结果,分别采用4种方法探索了塑性铰长度从屈服点到极限位移点的变化规律,研究了截面尺寸对梁试件塑性铰长度的影响.结果表明:屈服荷载后,随荷载的增加塑性铰长度逐渐增加;塑性铰长度表现出明显的尺寸效应.截面高度由200 mm增加到1 000 mm时,单调试件的峰值荷载点和极限位移点的相对塑性铰长度分别降低了40%和44%,低周往复加载试件则分别降低了38%和40%.在此基础上,提出的考虑截面高度影响系数的塑性铰长度计算值与试验值吻合较好.

钢筋混凝土框架节点梁端人工塑性铰新方案的探索

试验了6个足尺寸梁柱节点试件,其中采用3种人工铰方案。本文讨论两个新方案,其一是设置穿过核心并位于梁腹中部的两排附加钢筋,其间离柱边一定距离处开设水平缝;其二是离柱边一定距离处于梁下部设橡胶-钢板叠合体.试验结果表明,节点抗震性能优良.此外,本文提出了较方便的承载力计算方法和设置人工塑性铰的设计建议。

香港地区钢筋混凝土框架柱的抗震性能试验研究

通过6个框架柱模型的伪静力试验，研究了香港地区未考虑抗震设防的钢筋混凝土框架柱的抗震性能。根据试验结果，讨论了轴压比、配箍率、剪跨比等参数对其抗震性能的影响，分析了水平荷载作用时塑性铰区的弯曲变形、剪切变形和纵向钢筋粘结滑移变形所产生的位移在框架柱总水平侧移中所占的比例及其变化规律。