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 wails 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.

Bearing capacity of composite columns reinforced by concrete filled steel tube

In this study, nine simplified short composite columns consisting of core CFST (concrete filled steel tube) of different diameters and outer reinforced concrete were constructed to study their compressive performance under axial or eccentric compression. The failure mode is characterized by the crush of the outer concrete. The bearing capacity increases at first and then decreases with further increase of the position coefficient. It can be concluded that position coefficient is an important structural parameter that has considerable influences on the ultimate bearing capacity of the composite columns. The outer concrete, steel tubes and longitudinal reinforcement are found to work in a cooperative manner under axial or eccentric compression when the position coefficient is about 0.5. An improved bearing capacity algorithm that takes the position coefficient into account has been proposed based on the experimental and simulation results and current technical specification in China. It has been proven to be precise and safe.

圆钢管型钢再生混凝土组合柱滞回性能非线性有限元分析

基于圆钢管型钢再生混凝土组合柱低周反复荷载试验研究,采用OpenSees软件对该组合柱进行了滞回性能数值分析,获取了组合柱的滞回曲线及抗震性能指标,并与试验结果进行了比较,验证了组合柱数值模型的合理性。在此基础上,对组合柱的滞回性能开展了参数影响分析。结果表明:再生骨料取代率从0增大到100%,组合柱的峰值荷载下降了7.78%,延性略有降低;提高再生混凝土强度、型钢强度及圆钢管强度,对于提升组合柱的承载力及刚度是有利的,但却使组合柱的脆性增大;随着轴压比的增大,组合柱的承载力呈现先上升后下降的趋势,而延性逐渐变差;型钢配钢率从5.54%增至9.99%,组合柱的峰值荷载提高了24.34%,但对于改善组合柱的延性不明显;增大钢管壁厚对组合柱的承载力和延性均是有利的。

开槽侧板加强型连接梁柱节点子结构抗连续倒塌性能研究

为了优化侧板加强型节点的抗连续倒塌性能,提出了一种开槽侧板加强型梁柱连接节点形式。通过静力加载试验,得到了新型节点子结构的破坏模式、竖向抗力发展机制、应变分布、延性水平和动力承载力等。试验结果表明:钢梁翼缘在盖板附近首先开裂并向腹板外排螺栓中部延伸贯穿,导致竖向承载力快速下降为峰值荷载的20%左右。相比传统侧板加强型和圆弧扩盖板型梁柱节点,新型节点的峰值承载力分别提高了62.1%和19.6%,塑性弦转角分别提高了203.6%和25.8%。通过有限元分析得到了试件的断裂路径发展过程,进一步地通过参数化分析发现:扩大过焊孔构造对改善峰值后塑性弦转角及残余强度提升无明显作用;随着螺栓群远离钢梁翼缘起始断裂位置,最小残余强度比不断增大,但峰值后塑性弦转角呈先增大后减小的趋势;当螺栓群内移45mm时,峰值后塑性弦转角及最小残余强度比分别达到0.149rad和0.88,提高了38.2%和200.8%。

Seismic behavior of thin-walled circular and stiffened square steel tubed-reinforced-concrete columns

Steel tubed-reinforced-concrete(TRC) columns have been gradually used in the construction of high-rise buildings recently because of their high axial load-carrying capacities and excellent seismic behavior. Existing studies about their seismic behavior were focused on columns with relatively thick tubes, i.e., diameter-to-thickness/width-to-thickness(D/t) ratios were below 100,while little is known about thin-walled TRC columns, especially for square TRC columns. Considering the infilled concrete of square TRC columns is non-uniformly and non-effectively confined, accordingly, stiffened square TRC columns are usually adopted in practice. Thus, two thin-walled circular TRC columns(D/t=120) and two stiffened square ones with diagonal stiffeners in plastic hinge regions(D/t=106) were tested under a constant axial compression combined with cyclic lateral loading.Both the circular and stiffened square TRC columns had the same cross sectional area, tube thickness, reinforcing bar ratio and column height. Flexural failure occurred for all the four specimens. Test results showed the strengths of the stiffened square TRC columns were a little higher in comparison to their circular counterparts; the ductility and energy dissipation capacities were excellent for both the stiffened and circular TRC columns, indicating very good confinement was gained from the yielded steel tubes of the plastic hinge regions at the peak loads. And shear stresses(35–90 MPa) in the sheared plates showed their moderate contribution of carrying lateral loads. Finally, cross sectional capacity analysis results demonstrated the method for TRC columns is acceptable for the stiffened square TRC columns.

界面焊接环向钢筋的钢管混凝土叠合柱抗剪性能研究

为研究界面焊接环向钢筋的钢管混凝土叠合柱的抗剪性能,以环向钢筋的布置间距和直径为研究参数,对6根叠合柱试件进行了横向剪切静力试验和数值模拟,分析了各参数对试件的破坏过程、破坏形态、荷载-跨中挠度曲线以及抗剪承载力的影响规律。研究结果表明:界面环向钢筋布置方案不同的叠合柱试件破坏形态基本相同,均发生斜压破坏;试件的受力过程可划分为弹性阶段、弹塑性阶段、强化阶段和破坏阶段四个阶段;随着界面环向钢筋布置间距的减小,试件的抗剪承载力提高显著,最大增幅达22%;增大界面环向钢筋的直径可提高试件的抗剪承载力,但作用效果有限,最大增幅仅为6.1%。通过试验数据对有限元模型的有效性进行验证,并进一步分析了不同阶段有限元模型的应力状态,明确了此类叠合柱的受剪机理。

钢管混凝土叠合柱-H型钢梁外套筒式连接节点抗震性能试验与有限元研究

以钢管混凝土叠合柱为研究对象,设计了一种高强对穿螺栓连接的外套筒式梁柱节点。为了研究该新型节点的抗震性能和破坏机理,对3个缩尺比为1∶2的节点进行了拟静力试验。观察节点损伤过程及破坏模式,分析了梁端荷载-位移滞回曲线、骨架曲线、节点延性及耗能能力,采用ABAQUS软件建立有限元模型,研究套筒宽厚比和加强肋板厚度对节点抗震性能影响。试验及有限元研究结果表明:节点滞回曲线饱满,延性系数介于3.13~4.19之间,等效黏滞阻尼系数介于0.211~0.296之间,节点域的变形较大且耗能能力较强;随着套筒厚度增大,核心区混凝土开裂减少,破坏位置由节点外移至梁端截面;减小套筒宽厚比和增大加强肋板厚度可以有效提高节点刚度。为保证外套筒式节点达到刚性节点要求,建议套筒宽厚比不大于25,加强肋板厚度不小于梁翼缘厚度。

花瓣形钢管混凝土柱轴压受力机理和承载力研究

花瓣形钢管混凝土柱具有造型美观的优点,为具体研究其受力机理和承载力,定义了其截面组成,提出了截面偏移比和截面对称系数以反映花瓣形截面性质,提出在花瓣柱中设置十字形加劲肋以增强其组合效应。基于某工程中墩柱和有限元模型,研究了花瓣形钢管混凝土短柱在轴压荷载作用下的受力机理,分析了加劲肋厚度、混凝土强度、钢材强度、加劲肋开孔直径和间距等参数对轴压性能的影响,研究了加劲肋厚度与钢管壁厚的匹配关系。根据理论分析和大量有限元参数分析结果,建议了加劲肋厚度与钢管壁厚之比和钢管名义径厚比的取值范围,提出了花瓣形钢管混凝土短柱的轴压承载力计算式。

十字形钢管束高强混凝土组合剪力墙的抗剪承载力研究

为研究不同参数对十字形钢管束高强混凝土组合剪力墙抗剪承载力的影响,通过ABAQUS有限元软件建立了十字形钢管束高强混凝土组合剪力墙的有限元模型,重点考察钢材强度、混凝土强度、钢板厚度、钢管厚度、轴压比、墙体长度、墙体高度、腔体长度等参数对此类组合剪力墙抗剪承载力的影响。分析结果表明:随着钢材强度、钢板厚度、钢管厚度、墙体长度的增加和墙体高度的减小,试件的抗剪承载力呈显著增大趋势;随着混凝土强度的提高和腔体长度的减小,试件的抗剪承载力略呈增大趋势;当轴压比较小时(n∈(0,0.3]),轴压比对试件的抗剪承载力有一定的提高作用;当轴压比较大时(n∈(0.3,0.8]),随着轴压比的增加其抗剪承载力逐渐降低。最后,提出了十字形钢管束高强混凝土组合剪力墙的抗剪承载力计算公式。

钢框架+钢管混凝土束剪力墙结构装配式施工研究

以某市场升级改造工程为实例进行分析,研究钢框架和钢管混凝土束剪力墙结构体系在装配式施工中的应用。该工程采用了多层结构,其中地上主体结构采用了创新的钢框架和钢管混凝土束剪力墙结构,并详细探讨了该结构体系的结构优势以及装配率的计算方法。研究表明,钢管混凝土束组合结构住宅体系具有抗震性能好、施工周期缩短、工业化生产、现场装配化施工、节能环保等优点,对提高建筑工程的质量和效率具有重要意义。

螺旋箍筋约束钢管混凝土组合暗柱剪力墙抗震性能试验研究

研究以钢管等效代替约束边缘构件范围内的纵向受力钢筋,并在钢管外侧滚焊螺旋箍筋代替边缘构件箍筋的新型配置螺旋箍筋约束钢管混凝土组合暗柱的剪力墙结构的抗震性能.考虑高宽比、轴压比等参数设计制作新型配置螺旋箍筋约束组合暗柱的剪力墙与传统钢筋混凝土剪力墙进行低周反复荷载加载试验;分析了剪力墙的破坏形态、滞回性能、耗能能力、延性和刚度退化.研究结果表明:螺旋箍筋约束钢管混凝土组合暗柱对改善中高传统钢筋混凝土剪力墙承载能力和变形能力具有较好的效果,螺旋箍筋约束钢管混凝土组合暗柱的构造形式对耗散地震能量具有较好的作用.

轴压比对T形钢管束混凝土组合剪力墙抗震性能的影响研究

为研究轴压比对T形钢管束混凝土组合剪力墙抗震性能的影响,本文运用数值模拟软件ABAQUS设计并建立了轴压比为0、0.1、0.2、0.3、0.4、0.5、0.6、0.7、0.8的九个试件,进行有限元分析,系统分析了试件的抗震性能。分析结果表明:随着轴压比增大,T形钢管束混凝土组合剪力墙的承载能力有所降低,耗能能力有所提高;当轴压比大于0.6时,初始刚度显著降低。

钢框架-钢板墙和组合柱-钢梁框架振动台试验研究

为深入研究钢框架-钢板剪力墙和钢管混凝土柱-钢梁框架两种典型装配式结构体系的整体抗震性能和拓展其在高烈度区的应用,以甘肃省装配式示范工程中的两栋高层(10层)住宅建筑方案为原型,进行了1/8缩尺模型的地震模拟振动台试验。结果表明,钢框架-钢板剪力墙结构中的钢板剪力墙首先达到屈服状态,随后框架上出现塑性铰,塑性损伤主要集中在钢板墙及相邻梁端,个别1层柱脚出现损伤,体现了“多道抗震防线”的理念,巨震后(1.200g)结构的自振频率降幅约为19.5%(X向)和17.4%(Y向);钢管混凝土柱-钢梁框架结构的损伤主要在1层、4层及5层梁端,1层柱脚也出现少量塑性铰,体现了“强节点弱构件”的设计原则,巨震后结构的自振频率降幅约为19.5%(X向)和17.8%(Y向)。两类结构体系均能实现“小震不坏、大震不倒”的抗震设防目标,具有良好的抗震性能。此外,结构体系的侧向变形模式与整体结构的刚度分布密切相关,并且随着地震动峰值的增大愈加明显,钢框架-钢板剪力墙的抗侧刚度沿着高度呈降低趋势,整体呈现弯曲型的特征,钢管混凝土柱-钢梁框架(1层除外)抗侧刚度沿着高度分布较均匀,整体呈现剪切型的特征。

水平荷载下装配式钢-混凝土组合管剪力墙受力性能有限元分析

在3个剪跨比为1.65、轴压比为0.2的装配式钢-混凝土组合管(SRCT)剪力墙试件的低周往复加载试验基础上,选用合适的单元类型和材料本构关系等,建立了SRCT剪力墙的非线性数值分析模型。考察了轴压比、混凝土强度、钢材强度及拉结筋布置方式等对SRCT剪力墙水平荷载下受力性能的影响。结果表明:数值分析方法计算值与试验值吻合良好,可以较好地用于SRCT剪力墙在水平荷载下的受力分析;随着轴压比、混凝土强度及钢材强度的提高,SRCT剪力墙峰值承载力及初始刚度均有提高,但位移延性降低;梅花式拉结筋布置的SRCT剪力墙与并列式布置形式的SRCT剪力墙初始刚度和承载力相差不大,但位移延性大于并列式布置形式的SRCT剪力墙;在试验和数值分析的基础上给出影响SRCT剪力墙受力性能主要参数的取值范围。

钢管混凝土连接件横向连接剪力墙结构抗剪性能研究

为研究钢管混凝土连接件横向连接剪力墙结构的抗剪性能,采用ABAQUS对比钢管混凝土连接件横向连接剪力墙与现浇剪力墙结构的抗剪性能,探讨其可行性,分析钢管截面高度、混凝土强度、带槽角钢厚度等参数对其抗剪性能的影响。钢管混凝土连接件横向连接剪力墙试件与现浇试件相比、延性较高、极限承载力较高、初始刚度偏低;钢管截面高度对构件的破坏承载力影响最大,高度越高承载力越大;混凝土强度对构件的延性系数影响最大,强度越高延性系数降低越大;带槽角钢厚度对构件的初始刚度影响较大,厚度越厚初始刚度越大;钢材强度和钢管壁厚度对构件的抗剪性能影响较小;钢管内混凝土强度对构件的抗剪性能几乎无影响。钢管混凝土连接件横向连接剪力墙结构具有较高可行性;钢管截面高度是影响承载力的主要因素、混凝土强度是影响延性的主要因素、带槽角钢厚度是影响初始刚度的主要因素。

新型剪力墙钢结构体系建筑产业化技术研究

以新型剪力墙钢结构体系作为考察方向,重点研究钢管混凝土束剪力墙、异形钢管混凝土墙柱和波纹钢板剪力墙3种结构形式,采用理论研究、模型试验、软件分析、技术集成和工程示范等相结合的技术手段,依据钢管混凝土束生产、采购等产品的后端技术数据分析,进行了标准化、模块化和集成化建筑设计探索,分别完成了关键结构构件承载性能、建筑外保温材料防火性能和围护系统连接方式的试验研究,提出了钢结构外围护、保温、防火相结合的成套做法,改进了钢结构剪力墙的制作设备和施工工法,开发了适应典型气候区域的新型剪力墙钢结构体系成套技术,创新地采用战略加盟和“互联网+线下体验”的模式,将相应的技术成果进行产业化推广。

预制节段拼装双层钢管-混凝土组合墩柱抗震性能分析

为研究预制节段拼装CFDST墩柱的抗震性能,开展了预制节段拼装CFDST墩柱拟静力试验,并采用有限元软件ABAQUS对墩柱力学行为进行数值模拟,分析素混凝土层、初始预应力度和节段数量对墩柱抗震性能的影响.结果表明:在水平往复荷载作用下,墩柱未出现明显破坏,滞回曲线呈明显旗帜形,最大残余偏移率为0.18%,具有良好的自复位性能;最大偏移率为5.25%时,轴向预应力损失约为10.20%,墩身变形主要来自接缝处开口,正、负向最大累计开口量分别达到10.70和12.35 mm,存在明显的多转角变形模式;数值模型可以较好地模拟墩柱的非线性力学行为;考虑节段间素混凝土层可以更为合理地模拟墩柱滞回性能,提高初始预应力度可增强墩柱强度和耗能能力,而节段数量则对墩柱滞回性能影响较小.

钢管混凝土桁架弦杆界面传力特性分析

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