圆钢管混凝土边框内藏钢桁架剪力墙抗震性能试验研究

圆钢管混凝土边框内藏桁架剪力墙是一种新型组合剪力墙.为了解这种剪力墙的抗震性能,进行了 3个1/5缩尺试件的低周反复荷载试验.3个试件中,1个为圆钢管混凝土柱框架结构,1个为圆钢管混凝土边框-钢桁架结构,1个为圆钢管混凝土边框内藏钢桁架剪力墙.基于试验,对比分析了各试件的承载力、刚度及其退化过程、滞回特性、耗能能力及破...     

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。     

高轴压比下钢管混凝土边框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适用于高层及超高层建筑的新型组合剪力墙。轴压比是影响剪力墙抗震性能的一个主要因素,高层建筑底部轴压比较大。本文进行了1/4缩尺的1个普通钢筋混凝土剪力墙模型和1个钢管混凝土边框组合剪力墙模型在高轴压比下的低周反复荷载试验。在试验研究基础上,对比分析了剪力墙的承载力、延性、刚度及其衰减过程、滞回特性、耗能能力及破坏特征,建立了钢管混凝土边框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:在高轴压比下钢管混凝土边框组合剪力墙与普通剪力墙相比抗震性能显著提高。     

不同构造措施的钢管混凝土边框钢板剪力墙抗震性能试验研究

钢管混凝土边框钢板剪力墙是一种新型抗震剪力墙,为了比较不同构造措施对该新型剪力墙抗震性能的影响,进行了3个剪跨比为1.5的钢管混凝土边框钢板剪力墙低周反复荷载试验。其中,试验模型1为墙体钢板与边框柱钢管焊接,试验模型2为墙体钢板与边框柱钢管螺栓连接,试验模型3为墙体钢板开孔并与边框柱钢管焊接。通过试验研究,比较了各剪力墙的破坏特征、滞回特性、承载力、刚度、延性以及耗能能力。结果表明：在墙体钢板与边框柱钢管的连接方式中,采用焊接或栓接对剪力墙的整体性能影响不大;与普通钢管混凝土边框钢板剪力墙相比,钢板开孔钢管混凝土边框钢板剪力墙在开孔率不大的情况下,其承载力、延性、刚度和耗能能力没有明显变化。     

不同轴压比下钢管混凝土边框组合剪力墙抗震性能研究

钢管混凝土边框组合剪力墙是一种新型组合剪力墙.进行了2个1/4缩尺剪跨比为1.5的钢管混凝土边框组合中高剪力墙模型的低周反复荷载试验,模型1轴压比为0.35,模型2轴压比为0.65.在试验研究基础上,分析了轴压比对剪力墙承载力、延性、滞回特性、耗能能力的影响.建立了钢管混凝土边框组合中高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:钢管混凝土边框组合中高剪力墙抗震性能良好,具有重要的工程实用价值.     

内藏钢桁架混凝土组合低剪力墙抗震性能试验研究

进行了3个1/3缩尺的低剪力墙的抗震性能试验研究,包括1个普通混凝土低剪力墙、1个内藏钢框架混凝土组合低剪力墙和1个内藏钢桁架混凝土组合低剪力墙。在试验研究基础上,对比分析了各剪力墙的刚度及其衰减过程、承载力、延性、滞回特性、钢筋应变、耗能能力及破坏特征。试验表明:内藏钢框架和内藏钢桁架混凝土组合低剪力墙的抗震性能比普通混凝土低剪力墙明显提高。     

钢管混凝土叠合柱边框内藏钢桁架核心筒抗震性能试验研究

为进一步改善混凝土核心简的抗震性能,本文提出了钢管混凝土叠合柱边框内藏钢桁架组合核心筒.进行了2个1/6缩尺的核心筒模型在低周反复荷载下的抗震性能试验研究,1个为钢管混凝土叠合柱边框毛组合核心筒,1个为钢管混凝土叠合柱边框内藏钢桁架组合核心筒.通过试验,对比分析了2个核心简的承载力、延性、刚度及其衰减、滞回特性、耗能能力及破坏特征,给出了钢管混凝土叠合柱边框内藏钢桁架组合核心筒的承载力计算模型,计算结果与实测值符合较好.研究表明,钢管混凝土叠合柱边框内藏钢桁架组合核心筒与钢管混凝土叠合柱边框组合核心筒相比,其抗震性能明显提高.     

钢管混凝土叠合边框内藏钢桁架剪力墙振动台试验研究

进行了4个钢管混凝土叠合边框剪力墙模型的模拟地震振动台试验,包括:1个高宽比为1.6的钢管混凝土叠合边框剪力墙,1个高宽比为1.6的钢管混凝土叠合边框内藏钢桁架剪力墙,1个高宽比为3.0的为钢管混凝土叠合边框剪力墙,1个高宽比为3.0的钢管混凝土叠合边框内藏钢桁架剪力墙。试验中输入Taft地震波,测试了各试件在不同峰值加速度下的时程地震反应及其动力特性,分析了剪力墙损伤过程及破坏特征。研究表明,钢管混凝土叠合边框内藏钢桁架剪力墙比普通钢管混凝土叠合柱边框剪力墙承载力高、刚度退化慢、延性好、抗震耗能能力强。     

内藏钢桁架深连梁联肢剪力墙抗震性能试验研究

进行了1个1/7缩尺、剪跨比为2.0的带矩形钢管混凝土叠合柱边框内藏钢桁架深连梁联肢剪力墙模型的低周反复荷载试验。分析了该剪力墙的承载力、延性、滞回特性、耗能能力等抗震性能,研究了内藏钢桁架对该联肢剪力墙抗震性能的影响。试验研究表明:内藏钢桁架深连梁联肢剪力墙具有较好的延性;内藏钢桁架混凝土连梁对提高剪力墙的承载力及延性作用显著;带钢管混凝土叠合柱的翼墙可充分发挥钢管混凝土叠合柱抗压能力强、承载力高、不易开裂、延性好的优势;该新型组合剪力墙实现了"强墙肢、弱连梁"的延性屈服机制。     

钢管混凝土边框内藏钢板-钢撑低矮剪力墙抗剪性能分析

提出了钢管混凝土边框内藏钢板-钢撑组合剪力墙。为研究这种新型组合剪力墙的抗剪性能,在已有相关低矮剪力墙抗震性能试验基础上,进行了2个新的不同构造低矮剪力墙模型低周反复荷载试验。比较分析了两个试件的滞回特性、承载力、刚度、耗能和破坏特征,提出了抗剪承载力计算公式,计算与实测符合较好。研究表明:钢管混凝土边框,对墙体主斜裂缝发展有明显约束作用;不同构造剪力墙,墙体裂缝开展与损伤过程有明显差异;边框、钢板-钢撑和墙体的设计参数应合理匹配,以提高剪力墙的延性和抗震耗能能力。     

Research on seismic performance of shear walls with concrete filled steel tube columns and concealed steel trusses

In order to further improve the seismic performance of RC shear walls, a new composite shear wall with concrete filled steel tube (CFT) columns and concealed steel trusses is proposed. This new shear wall is a double composite shear wall; the first composite being the use of three different force systems, CFT, steel truss and shear wall, and the second the use of two different materials, steel and concrete. Three 1/5 scaled experimental specimens: a traditional RC shear wall, a shear wall with CFT columns, and a shear wall with CFT columns and concealed steel trusses, were tested under cyclic loading and the seismic performance indices of the shear walls were comparatively analyzed. Based on the data from these experiments, a thorough elastic-plastic finite element analysis and parametric analysis of the new shear walls were carried out using ABAQUS software. The finite element results of deformation, stress distribution, and the evolution of cracks in each phase were compared with the experimental results and showed good agreement. A mechanical model was also established for calculating the load-carrying capacity of the new composite shear walls. The results show that this new type of shear wall has improved seismic performance over the other two types of shear walls tested.     

Analysis and seismic tests of composite shear walls with CFST columns and steel plate deep beams

A composite shear wall concept based on concrete filled steel tube （CFST） columns and steel plate （SP） deep beams is proposed and examined in this study. The new wall is composed of three different energy dissipation elements： CFST columns; SP deep beams; and reinforced concrete （RC） strips. The RC strips are intended to allow the core structural elements - the CFST columns and SP deep beams - to work as a single structure to consume energy. Six specimens of different configurations were tested under cyclic loading. The resulting data are analyzed herein. In addition, numerical simulations of the stress and damage processes for each specimen were carried out, and simulations were completed for a range of location and span-height ratio variations for the SP beams. The simulations show good agreement with the test results. The core structure exhibits a ductile yielding mechanism characteristic of strong column-weak beam structures, hysteretic curves are plump and the composite shear wall exhibits several seismic defense lines. The deformation of the shear wall specimens with encased CFST column and SP deep beam design appears to be closer to that of entire shear walls. Establishing optimal design parameters for the configuration of SP deep beams is pivotal to the best seismic behavior of the wall. The new composite shear wall is therefore suitable for use in the seismic design of building structures.     

Cyclic tests on a hybrid coupled wall utilizing a rocking mechanism

A new type of hybrid coupled wall system, consisting of rolled steel coupling beams, reinforced concrete (RC) wall piers, and concrete‐filled tube (CFT) short columns, is introduced. In this new system, the bases of the wall piers are connected to the base beams only through CFT short columns, unlike conventional coupled walls. Yield occurs in the coupling beams and the short columns; hence, in the RC wall piers, only minimum cracking appears. A total of four subassembly specimens, designed to fail in various collapse mechanisms, were cyclically loaded under constant axial force. A benchmark specimen showed ductile behavior with large energy dissipation until fracture occurred in the coupling beam. In the specimen designed to fail in shear in its CFT, substantial axial shortening was observed, but the overall behavior was ductile. Behavior of specimens with small amounts of section steel in the wall panel fringe, or with thin wall panels, also showed ductile behavior, but the strength and energy dissipation were significantly smaller than other two specimens. An analytical model was proposed for a frame analysis program using fiber elements to simulate elastic–plastic behavior of the system. Design methods to prevent shear failure of CFT and RC panels are suggested using the analytical and test results. Copyright © 2008 John Wiley & Sons, Ltd.     

装配式内藏钢桁架混凝土剪力墙抗震性能试验研究

为了提高装配式剪力墙的抗震性能,提出并设计了一片暗柱内置H型钢装配式内藏钢桁架混凝土剪力墙及一片暗柱内置圆钢管装配式内藏钢桁架混凝土剪力墙,其中H型钢竖向连接采用顶底角钢复合连接,圆钢管竖向连接采用端板焊接.通过对试件进行低周反复加载试验,得到剪力墙试件的破坏模式、滞回曲线、承载力、延性、残余变形、刚度退化和耗能能力等...     

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.