轻钢骨混凝土剪力墙延性的非线性有限元分析

轻钢骨混凝土剪力墙结构作为新型结构在工程界要得到认同并推广使用,必须对该结构的各项性能指标进行系统的试验研究和理论分析。本文应用ADINA有限元软件对轻钢骨混凝土剪力墙延性进行非线性有限元分析,根据不同的高宽比、轴压比、轻钢骨配筋率以及端部配筋模型的计算结果,对该结构体系的延性及其破坏形态进行综合分析,并对轻钢骨混凝土剪力墙轴压比设计提出建议。分析结果表明,高宽比主要控制轻钢骨混凝土剪力墙的破坏形态,轴压比对其结构的延性的影响最为显著,而端部配筋对其延性影响不大。     

钢筋混凝土开洞剪力墙结构抗震非线性有限元分析

本文以钢筋混凝土开洞剪力墙结构为研究对象，建立了该类结构动力非线性有限元分析计算及该类结构静力非线性pushover有限元分析计算的基本过程，并编制了相应的计算机程序．通过与实验分析结果的比较，检验了本文动力非线性有限元分析计算方法的准确程度，验证了静力非线性pushover有限元分析方法应用于开洞剪力墙抗震非线性性能评估的可靠性。     

高强混凝土剪力墙地震损伤模型分析

在分析比较现有钢筋混凝土结构的地震损伤模型的基础上,根据高强混凝土剪力墙的滞回曲线特性及刚度退化规律,采用能量耗散系数和最大变位处的卸载刚度的退化为破坏参数,提出了适用于高强混凝土剪力墙构件的双参数地震损伤模型。依据已有的高强混凝土剪力墙构件试验研究结果,对损伤模型进行非线性回归分析,确定了相应的地震损伤模型参数,提出了高强混凝土剪力墙各性能水平的损伤指数以及相应于三水准抗震设防的损伤指数允许值。分析结果表明,按本文所提出的损伤模型计算得到的剪力墙构件最终破坏时对应的损伤指数,其平均值在合理范围内,标准差较小;损伤指数计算值对应的损伤程度基本符合试验结果,计算结果离散程度较低。     

钢管混凝土边框高强混凝土组合剪力墙抗震性能试验研究

钢管混凝土边框组合剪力墙是一种新型组合剪力墙。本文进行了2个1/4缩尺的高强混凝土剪力墙模型的低周反复荷载试验,模型1为普通钢筋混凝土剪力墙,模型2为钢管混凝土边框组合剪力墙。在试验研究基础上,对比分析它们的承载力、延性、刚度及其衰减过程、滞回特性、耗能能力及破坏特征,建立了组合剪力墙的承载力计算模型,计算结果与实测结果符合较好。研究表明,钢管混凝土边框高强混凝土组合剪力墙与普通剪力墙相比抗震性能显著提高。     

高强钢筋高强混凝土框架结构非线性地震反应分析

研究配有高强钢筋的高强混凝土框架结构的抗震性能.采用OpenSees开放式软件对配有高强钢筋的高强混凝土框架结构进行了地震作用下的非线性有限元分析,并将计算结果与同等参数条件下的结构拟动力试验进行了对比.得到不同峰值加速度情况下的结构层间反应时程曲线,层间位移滞回曲线,以及破坏模式等,数值计算结果与试验吻合程度较好.研究结果表明利用基于OpenSees的有限元分析方法,能够有效地分析配有高强钢筋的高强混凝土框架结构的地震响应,可以辅助研究该结构的抗震性能.     

L形高强钢筋高强混凝土短肢剪力墙抗震性能试验研究

L形短肢剪力墙由于其肢短的特点,已经广泛应用于民用建筑的外围结构。为研究使用高性能材料加强后的新型L形短肢剪力墙的抗震性能,本文基于不同轴压比、高宽比和配箍率,设计制作了六片短肢剪力墙试验模型,对其进行了低周往复荷载试验,根据试验结果,对试件的滞回性能、刚度退化、破坏形态、耗能能力等抗震性能指标进行分析与研究。结果表明:高强材料的使用提高了试件的整体承载能力;在满足最小配箍率的前提下适当增大配箍率有利于提高试件的承载力和延性;轴压比大小是影响试件破坏形态的主要因素,随着轴压比逐渐增大,试件趋于脆性破坏;高厚比大小是影响试件抗震性能的次要因素,其影响程度主要根据工程实际情况来确定,但可以肯定的是,较大高厚比有利于提升墙体的稳定性和承载能力。     

钢筋混凝土带暗支撑低矮剪力墙非线性有限元分析

在试验研究基础上，采用ANSYS有限元分析程序，对钢筋混凝土带暗支撑低矮剪力墙在单向加载下的性能作了非线性分析，从理论计算角度进一步了解其在水平荷载作用下的开裂，变形及破坏全过程，有限元分析与试验结果符合较好。     

高强钢筋高强混凝土一字形截面短肢剪力墙抗震性能试验研究

对6片配置HRB500高强钢筋高强混凝土一字形截面短肢剪力墙进行低周反复荷载试验,通过改变试件的轴压比、截面高厚比和墙肢端部箍筋间距,研究其破坏模式、承载力,变形能力、延性、滞回性能和耗能能力.试验结果表明:高强钢筋高强混凝土一字形截面短肢剪力墙的破坏模式为弯曲破坏为主的弯剪破坏;墙肢端部密配高强箍筋可以对短肢剪力墙提...     

CFRP加固混凝土框架结构非线性有限元动力分析

对碳纤维布(CFRP)抗震加固混凝土框架结构进行了非线性有限元动力分析。分析中考虑了CFRP约束混凝土后，混凝土物理特性的变化。建立了CFRP约束混凝土框架结构地震反应时程分析的方法；最后，应用本方法，对CFRP约束的钢筋混凝土框架结构进行了在罕遇地震作用下的时程分析，并根据计算结果进行了分析讨论。     

型钢高强混凝土短肢剪力墙-连梁节点抗震性能试验研究

通过4个型钢高强混凝土短肢剪力墙-连梁节点试件和1个高强混凝土短肢剪力墙-连梁节点试件的低周反复荷载试验,主要研究配钢形式、轴压比和连梁结构类型对节点的滞回特性、变形能力及耗能能力等性能的影响。结果表明:型钢高强混凝土短肢剪力墙-连梁节点的滞回曲线饱满,承载力、刚度以及抗震性能较高强混凝土短肢剪力墙节点均有所改善,所有试件的延性均小于3,极限层间位移角均小于1/100,等效黏滞阻尼系数在0.17～0.24之间,表现出其延性和抗倒塌能力较差,耗能能力较好。     

钢筋混凝土筒体的非线性有限元分析模型

本文提出了一种反复荷载下混凝土材料的本构模型，该模型采用平面应力状态下的弥散正交裂缝假设，钢筋采用弥散假设，并考虑了屈服、应变硬化、循环卸载与再加载规则等因素。该本构模型与其他模型相比，具有简便有效的优点。在此基础上，本文采用八结点平面应力单元建立了钢筋混凝土核心筒体非线性有限元分析模型，并对试验模型进行了非线性分析，计算结果与试验结果吻合较好。     

H形断面钢筋混凝土立体剪力墙的非线性动力响应分析

为了建立统一的动力响应分析模型,本文以NUPEC振动台试验的H形断面钢筋混凝土立体剪力墙为研究对象进行了三维非线性有限元动力响应分析。根据分析结果与试验结果的比较可知,在RC剪力墙到达最大承载力之前由简化模型和一般模型得到的动力响应特性与试验结果吻合较好,荷载-变形关系能很好模拟试验结果。但是,最大承载力之后,由于混凝土开裂、损伤、劣化的急剧发展,较难模拟混凝土开裂、裂缝的开闭及滑移等非线性特性,分析得到的加速度衰减较慢、位移响应较小。基于上述研究成果探讨并提出了进一步改善非线性有限元动力响应分析精度的建议。     

Dynamic non-linear analysis of reinforced concrete shear wall by finite element method with explicit analytical procedure

A numerical procedure for a dynamic non-linear finite element analysis is proposed here to analyse three-dimensional reinforced concrete shear wall structures subjected to earthquake motions. A shear wall is modelled as a quasi-three dimensional structure which is composed of plane elements considering the in-plane stiffness of orthogonal flange panels. The proposed constitutive model is based on the non-linearity of reinforcement and concrete in which the tension stiffening in tension and the degradation of stiffness and strength in compression of concrete after cracking are considered. The acceleration-pulse method, which is a kind of explicit analytical procedure, is employed to solve the non-linear dynamic equations, where the dynamic equation can be solved without stiffness matrix and so the iterative procedure is not necessary for descending portion of stress–strain relationship caused by cracking and softening after compressive strength in concrete. The damping effect is considered by assuming equivalent viscous damping which can give good cyclic behaviours of inertia force vs. displacement relationships. This analytical method was applied to a test specimen of a reinforced concrete shear wall with a H-shaped section which was vibrated up to failure by using a large-scale shaking table with high -performance in Japan. The test was performed as one of the dynamic model tests for evaluation of seismic behaviour of nuclear reactor buildings. The calculations were performed sequentially from the elastic range to failure. The comparison with the test results shows that this approach has good accuracy. © 1997 by John Wiley & Sons Ltd     

Nonlinear finite element analysis of high-strength concrete columns and experimental verification

This paper describes a nonlinear finite element （FE） analysis of high strength concrete （HSC） columns, and verifies the results through laboratory experiments. First, a cyclically lateral loading test on nine cantilever column specimens of HSC is described and a numerical simulation is presented to verify the adopted FE models. Next, based on the FE model for specimen No.6, numerical simulations for 70 cases, in which different concrete strengths, stirrup ratios and axial load ratios are considered, are presented to explore the effect of these parameters on the behavior of the HSC columns, and to check the rationality of requirements for these columns specified in the China Code for Seismic Design of Buildings （GB 50011- 2001）. In addition, three cases with different stirrup strengths are analyzed to investigate their effect on the behavior of HSC columns. Finally, based on the numerical results some conclusions are presented.     

钢筋混凝土核心筒体抗震性能分析

本文在非线性有限元计算模型和分析程序的基础上，对影响钢筋混凝土核心筒体抗震性能的三个重要参数，即高宽比、轴压比、连梁刚度比，进行了一系列模型的非线性计算分析，得出了各参数对核心筒的承载力、破坏形式、延性、耗能能力等抗震性能的影响，为参数影响的定量研究和工程设计提供了有价值的参考。     

A regularized fiber element model for reinforced concrete shear walls

Reinforced concrete shear walls are used because they provide high lateral stiffness and resistance to extreme seismic loads. However, with the increase in building height, these walls have become slenderer and hence responsible of carrying larger axial and shear loads. Because 2D/3D finite element inelastic models for walls are still complex and computationally demanding, simplified but accurate and efficient fiber element models are necessary to quickly assess the expected seismic performance of these buildings. A classic fiber element model is modified herein to produce objective results under particular loading conditions of the walls, that is, high axial loads, low axial loads, and nearly constant bending moment. To make it more widely applicable, a shear model based on the modified compression field theory was added to this fiber element. Consequently, this paper shows the formulation of the proposed element and its validation with different experimental results of cyclic tests reported in the literature. It was found that in order to get objective responses in the element, the regularization techniques based on fracture energy had to be modified, and nonlinearities because of buckling and fracture of steel bars, concrete crushing, and strain penetration effects were needed to replicate the experimental cyclic behavior. Thus, even under the assumption of plane sections, which makes the element simple and computationally efficient, the proposed element was able to reproduce the experimental data, and therefore, it can be used to estimate the seismic performance of walls in reinforced concrete buildings. Copyright © 2016 John Wiley & Sons, Ltd.     

Study on a new shear wall system with shaking table test and finite element analysis

A new seismic energy dissipation shear wall structure is proposed in this paper. The new shear wall is one with purposely built‐in vertical slits within the wall panel, and rubber belts as seismic energy dissipation devices are installed in the vertical slits. In order to verify this concept, shaking table tests of a 10‐storey shear wall model with rubber belts filled in the vertical slits were carried out, and comparison of seismic behaviour was made between the new shear wall system and a shear wall with reinforced concrete connecting beams as energy dissipation. Furthermore, the seismic behaviour of this new shear wall is analysed by a finite element time history analysis method. The test and analysis show that the new shear wall system has a very good ability to dissipate seismic energy and is easy to use in engineering practice. Copyright © 2000 John Wiley & Sons, Ltd.