Lateral load-carrying capacity analyses of composite shear walls with double steel plates and filled concrete with binding bars

A method is developed to predict the lateral load-carrying capacity of composite shear walls with double steel plates and filled concrete with binding bars(SCBs). Nonlinear finite element models of SCBs were established by using the finite element tool, Abaqus. Tie constraints were used to connect the binding bars and the steel plates. Surface-to-surface contact provided by the Abaqus was used to simulate the interaction between the steel plate and the core concrete. The established models could predict the lateral load-carrying capacity of SCBs with a reasonable degree of accuracy. A calculation method was developed by superposition principle to predict the lateral load-carrying capacity of SCBs for the engineering application. The concrete confined by steel plates and binding bars is under multi-axial compression; therefore, its shear strength was calculated by using the Guo-Wang concrete failure criterion. The shear strength of the steel plates of SCBs was calculated by using the von Mises yielding criterion without considering buckling. Results of the developed method are in good agreement with the testing and finite element results.

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.

Experimental and analytical study on seismic behavior of steel-concrete multienergy dissipation composite shear walls

In this paper, a steel-concrete multi-energy dissipation composite shear wall, comprised of steel-reinforced concrete （SRC） columns, steel plate （SP） deep beams, a concrete wall and energy dissipation strips, is proposed. In order to study the multi-energy dissipation behavior and restorability after an earthquake, two stages of low cyclic loading tests were carded out on ten test specimens. In the first stage, test on five specimens with different number of SP deep beams was carried out, and the test lasted until the displacement drift reached 2%. In the second stage, thin SPs were welded to both sides of the five specimens tested in the first stage, and the same test was carried out on the repaired specimens （designated as new specimens）. The load-bearing capacity, stiffness, ductility, hysteretic behavior and failure characteristics were analyzed for both stages and the results are discussed herein. Extrapolating from these results, strength calculation models and formulas are proposed herein and simulations using ABAQUS carried out, they show good agreement with the test results. The study demonstrates that SRC columns, SP deep beams, concrete wall and energy dissipation strips cooperate well and play an important role in energy dissipation. In addition, this study shows that the shear wall has good recoverability after an earthquake, and that the welding of thin SP＇s to repair a deformed wall is a practicable technique.

Pseudo-dynamic testing of a fabricated composite frame with steel plate shear walls

A pseudo-dynamic testing program was generated on a fabricated composite frame with steel plate shear walls （SPSWs） to study its seismic perlbrmance. The specimen was a three-storey single-bay frame, which was composed of H- section steel columns and composite beams, and was assembled by bolted height-adjustable steel beam-to-column connections （BHA connections）. Beam-only-connected SPSWs were selected as lateral load resisting members. The specimen was subjected to four ground motions of progressively increasing intensity. The results showed that： （1） beam-only-connected S PSWs provided sufficient lateral load resistance, lateral stiffness, and energy dissipation capacity to the fabricated frame via the tension ficld action developed in their infill panels; （2） the fabricated frame, assembled by BHA connections, exhibited substantial redundancy and good ductility; （3） an undesirable failure mode of the fabricated frame, in huge earthquakes, included severe cracking in composite beams and block shear failure in SPSWs＇ connections; （4） the inter-storey shear force distribution determined by ASCE/SE1 7-10 was verified with experimental data.

焊接多腔双钢板-混凝土组合剪力墙抗震性能分析

大多数双钢板-混凝土组合剪力墙采用螺栓连接或焊接肋的方式使钢板和混凝土协同工作。然而,这种连接方式可能导致整体性和塑性变形效率较低,且制作复杂,焊接多腔双钢板-混凝土组合剪力墙能够有效地避免这些问题。为了深入研究焊接多腔双钢板-混凝土组合剪力墙的抗震性能,基于约束混凝土真三轴塑性-损伤本构模型和钢材弹塑性混合强化-韧性损伤本构模型,建立了组合剪力墙的精细化三维实体-壳模型,将模拟所得的滞回曲线、骨架曲线、刚度退化曲线、弹性刚度、承载力、累积耗能、等效阻尼粘滞系数和延性系数与已有拟静力试验结果相比较,发现两者吻合较好。分析结果表明:轴压比对组合剪力墙模型算例刚度和承载力的影响较小,而随剪跨比增大,组合剪力墙模型算例的刚度和承载力呈线性降低;轴压比对组合剪力墙模型算例总塑性耗能的影响较小,而剪跨比的影响较大,剪力墙总塑性耗能随剪跨比增大而降低;轴压比和剪跨比都不会改变算例各部件的耗能分配机制,即组合剪力墙模型算例以外钢板和内隔板耗能为主。

带PBL剪力键的钢芯板混凝土组合剪力墙低周往复加载试验研究

为研究带PBL剪力键的钢芯板混凝土组合剪力墙的抗震性能,对1个型钢混凝土组合剪力墙和4个钢芯板混凝土组合剪力墙进行了循环往复加载试验;观察带PBL剪力键的钢芯板混凝土组合剪力墙在水平循环荷载下的破坏全过程,并分析该类剪力墙的滞回特征、变形能力、承载能力、耗能性能、刚度和强度退化能力。结果表明:钢芯板混凝土组合剪力墙的破坏模式主要为弯曲型破坏,滞回曲线较为饱满;配置钢芯板的剪力墙承载力、延性性能和耗能能力较优;PBL剪力键的构造方式可保证钢芯板与混凝土之间的黏结性能完好,PBL剪力键平放会导致剪力墙出现沿PBL剪力键的水平通缝,影响剪力墙承载能力的发挥,建议采用PBL剪力键竖放的构造形式。

低周反复荷载下T型双波纹钢板混凝土组合剪力墙受力性能试验研究

为研究低周反复荷载下T型双波纹钢板混凝土组合剪力墙的受力性能,对5个T型双波纹钢板混凝土组合剪力墙进行了低周反复加载试验。基于试验数据,分析了T型组合剪力墙的破坏模式、滞回曲线、变形能力及耗能能力,重点研究了边缘约束条件、波纹类型以及轴压比不同变化参数对T型组合剪力墙抗震性能指标的影响规律。研究结果表明:T型双波纹钢板混凝土组合剪力墙破坏模式主要有压屈破坏和压弯破坏两种;设置边缘约束构件是提高T型双波纹钢板混凝土组合剪力墙承载能力和变形能力的关键因素;纵向窄波纹钢板对内部混凝土的约束能力更强,在低周反复荷载下两者协同工作性更优,而横向窄波纹钢板试件强度退化最严重;采用全截面塑性设计方法进行T型双波纹钢板混凝土组合剪力墙正截面承载力计算,试验值与计算值吻合良好;T型双波纹钢板混凝土组合剪力墙具有较好的承载能力和变形能力,可适用于高层及超高层建筑结构中。

温度影响下不同轴压比双钢板混凝土组合剪力墙抗震性能

研究不同温度环境下不同轴压比双钢板混凝土组合剪力墙的抗震性能,以温度(40、20、-40℃)和轴压比(n=0.3、0.4、0.5、0.6)为控制参数,设计了12片剪力墙。利用ABAQUS对双钢板组合剪力墙试验进行对比验证,验证有限元结果的准确性。通过对12个剪力墙的承载能力、塑性变形能力、耗能能力、延性对比分析,探究其在代表性温度环境下轴压比对试件的抗震性能变化规律。结果表明,在相同的温度环境下,随着轴压比的增加,剪力墙的承载能力增加,延性降低。轴压比对于刚度退化的影响不明显。在20℃环境下,剪力墙的延性好于40和-40℃环境下延性。-40℃环境下,剪力墙的承载能力高于40和20℃环境。

装配式带夹芯保温槽型玻璃钢-钢板-槽钢-混凝土组合剪力墙轴压性能研究

提出一种装配式带夹芯保温槽型玻璃钢-钢板-槽钢-混凝土组合剪力墙,设计3个具有不同配筋形式和混凝土种类的墙板试件进行轴心受压试验,获得墙板在轴压作用下的破坏模式、荷载-位移曲线、荷载-应变曲线、承载力储备系数、延性系数、材料利用率等性能指标。通过ABAQUS有限元分析软件对墙板进行参数化分析,研究内嵌钢板强度和厚度对其轴压性能的影响。结果表明,墙板具有良好的承载力储备能力和延性性能;混凝土中掺入1%体积比的钢纤维可显著提高墙板内混凝土的抗拉性能,使混凝土强度得到更加充分的利用,布置钢筋可以显著提高墙板延性;墙板的承载力和延性随内嵌钢板厚度和强度的增加而增大,强度为Q355、厚度为4、6mm时,墙板材料利用率更高。提出适用于该类墙板的轴压承载力设计公式,考虑钢板屈曲和截面组合效应的墙板轴心受压承载力设计公式计算结果较精确。

双钢板混凝土组合墙偏心受压性能试验研究

为了研究双钢板混凝土组合墙在偏心受压荷载下的结构性能,设计制作了5个试件,以偏心距离和墙板厚度作为研究参数,进行偏心受压试验.利用ABAQUS软件对试件进行有限元分析,并采用截面分析法计算试件在轴力与弯矩共同作用下的截面承载力.试验结果表明,试件最终出现钢板局部屈曲与混凝土受压破坏.根据试验荷载-位移曲线,计算得到试件延性系数为1.28~1.92.墙厚相同时,随着加载偏心距离的增加,承载力逐渐下降.偏心距离相同时,增加墙体厚度可以有效提高试件承载能力.偏心受压试件的截面应变分布满足平截面假定.承载力试验值与有限元模型计算值和理论计算值的最大误差分别为4%和9%.

轴压荷载作用下双钢板-混凝土组合剪力墙中钢板屈曲性能研究

双钢板-混凝土组合剪力墙作为建筑物中的抗侧力构件,具有承载力高、耗能能力强和延性好等优点。在高层和超高层建筑结构中,双钢板-混凝土组合剪力墙需要承担一定的竖向荷载,钢板在正常使用阶段要求不发生弹性屈曲。钢板初始几何缺陷是影响双钢板-混凝土组合剪力墙轴压荷载下钢板屈曲应力的重要指标,而在以往的研究中,钢板屈曲应力的计算方法并未予以考虑。基于前期的双钢板-混凝土组合剪力墙轴压试验研究,采用分析软件ABAQUS建立了双钢板-混凝土组合剪力墙轴压试件有限元模型,模型中引入了钢板的初始几何缺陷,从钢板屈曲应变、荷载-位移曲线和破坏模态等方面与试验结果进行对比,验证了模型分析结果的合理性。在此基础上进行参数分析,系统研究了钢板初始几何缺陷、钢板距厚比和钢材屈服强度等参数对钢板屈曲性能的影响规律,基于试验和数值模拟分析结果,提出了考虑钢板初始几何缺陷影响的双钢板-混凝土组合剪力墙钢板屈曲应力计算方法。

巨型钢框架-双钢板组合剪力墙住宅体系力学性能探究

在巨型结构体系的基础上提出巨型钢框架-双钢板组合剪力墙住宅体系。基于实际超高层混凝土住宅工程背景建立高度为156 m的计算模型,对其进行弹性反应分析及弹塑性时程分析以评估结构力学性能。通过对比主次结构不同的连接假定,探究主次结构连接方式对于结构整体性能及关键结构构件的影响。基于ABAQUS软件分析了次结构与双钢板组合剪力墙之间采用不同连接方式对剪力墙各部件的影响。最后对该结构体系进行经济性分析。研究结果表明:该结构体系能满足建筑户型无柱大空间设计要求且具有优良的力学性能和经济性指标,在设计中主、次结构连接推荐采用铰接连接。研究结果可为巨型钢框架-双钢板组合剪力墙结构的设计提供参考。

钢板-混凝土组合剪力墙裂缝控制及监测分析

以实际工程为背景,对1.7 m厚钢板-混凝土组合剪力墙的裂缝控制及监测进行分析。大体积混凝土构件,由于其水化热比较高容易产生温度裂缝,基于此首先对原材料及配合比进行优化设计,降低混凝土水化热。然后对大厚度组合剪力墙浇筑后采取合理的养护措施控制其内部温度以及对裂缝发生情况进行实测分析,最后经过一系列针对性的裂缝控制措施及监测结果表明,采用优化设计对大厚度组合剪力墙的裂缝控制优于同类工程的裂缝控制效果。

组合钢板剪力墙分层浇筑模拟及温度场分析

由于雄安新区创新研究院科研园区项目钢板混凝土组合剪力墙高度较高,并且要求普通混凝土强度等级达到C50及以上,混凝土下落高度过大,易产生离析现象,影响工程质量,所以采取逐层浇筑、逐层振捣的施工方式进行模拟。该方法下,墙体温度场无法通过理论计算得出,故基于ABAQUS2021进行有限元模拟,编写Hetval子程序对混凝土水化放热过程进行精确模拟,得到了分层浇筑措施下组合钢板剪力墙的混凝土水化放热温度场,为工程顺利完工交付提供了技术支持。

纤维增强钢复合板剪力墙力学性能研究

为了提升钢板剪力墙的力学性能,文中主要对不同纤维粘贴方式下纤维复合板剪力墙的拉伸、压缩及弯曲性能进行研究。结果表明,与纯钢板相比,水平纤维钢板的极限拉伸荷载、极限压缩荷载以及极限弯曲荷载分别增加32.5%、43.3%及67.8%。垂直纤维钢板与纯高强钢板的刚度值基本一致,而水平纤维钢板的拉伸刚度较纯高强钢板高21.5%,压缩刚度较纯高强钢板高27.2%,弯曲刚度较纯高强钢板高114.3%,耗散能能量为38.2 kJ。与钢板墙相比,水平纤维增强钢复合板剪力墙耗散能力提升16.3%,初始刚度提升14.6%。

装配式双面叠合剪力墙施工技术及构造分析

随着我国装配式结构体系的发展和建筑节能化的推进,叠合剪力墙结构得到广泛的使用,与传统的现浇剪力墙相比,叠合剪力墙具有施工便捷、工业化水平高、成本低等特点。该文以某装配式双面叠合剪力墙住宅楼项目为依托,介绍装配式双面叠合剪力墙的工艺流程,总结施工过程中的控制要点,以保证叠合剪力墙的工程质量。同时借助数值分析软件对双面叠合剪力墙的构造措施展开分析,计算结果表明,增加桁架钢筋直径能提高竖向承载力;改为钢筋笼拉结形式可以提高延性和耗能能力。

丰城紫云大桥组合钢板梁设计

丰城市紫云大桥陆上引桥采用连续组合钢板梁,南岸标准段跨径布置为(34.5+2×36+3×42+2×36+34.5)m。主梁采用双主梁组合钢板梁结构,小横梁体系,梁高2.1 m。钢梁由焊接工字钢纵梁、中间小横梁以及支点横梁等组成,中支点两侧各约0.125 L范围内的钢纵梁纵向板件采用Q420qD钢,其余钢材采用Q345qD钢。桥面板采用全宽预制的预应力混凝土桥面板,湿接缝混凝土采用超高性能混凝土(UHPC),预制桥面板纵向钢筋外伸长度大于10 d,无需现场焊接或绑扎。板梁连接采用新型灌浆剪力键,钢梁与桥面板通过焊钉连接件、槽口、高强砂浆填充料、注浆孔、通气孔以及橡胶条,形成一个完全连接的整体。钢梁采用临时支架分段吊装施工,预制桥面板采用先吊装结合正弯矩区桥面板后负弯矩区桥面板的顺序铺设。对结构进行强度、稳定和变形分析,结果均满足设计要求。

内置钢板组合剪力墙剪切性能研究

为研究带栓钉的内置钢板组合剪力墙抗剪性能及承载力变化规律,文中开展了4个带栓钉的内置钢板组合剪力墙抗剪试验,并通过ABAQUS有限元软件研究了不同约束边缘构件和不同型钢含钢率对剪力墙剪切性能的影响。研究结果表明:随着高宽比的减小,组合剪力墙由弯曲变形转向剪切变形转变,抗侧刚度和荷载值都有明显提高,但延性随之降低。随着边缘构件约束的增强,剪力墙各阶段的刚度和承载力提高很大,其变形能力也会相应提高。随着约束边缘构件含钢率的增加,剪力墙的极限承载力和变形能力也逐渐增强。

格栅管式双钢板组合剪力墙抗震性能的有限元分析

基于钢材延性损伤和混凝土三向约束的塑性损伤的有限元分析模型,进行格栅管式双钢板组合剪力墙抗震试验仿真分析,开展试验结果与有限元结果对比分析。研究表明:格栅管式双钢板墙三向约束管内混凝土,管内混凝土强度和延性大幅度提高;管内混凝土保护了外侧双钢板,避免了外侧双钢板受压屈曲破坏,二者协同工作,优势互补,其极限水平位移角为1/35左右。

竖波钢板组合剪力墙截面性能及曲率分析

现行基于承载力的抗震设计方法缺乏对构件截面性能的准确反映,对于剪力墙等重要抗侧力构件在地震作用下的性能要求缺乏体现。竖波钢板组合剪力墙因内嵌波形钢板的几何形状优势,表现出良好的抗震性能,对其截面性能的分析有待研究。该文基于竖波钢板组合剪力墙的组合机理和破坏现象,提出截面曲率的理论计算方法,给出荷载-位移曲线转化为弯矩曲率曲线的计算过程,通过试验数据验证了理论计算方法的准确性以及数值计算模型的适用性。扩展研究波形钢板几何参数、约束边缘H型钢、分布钢筋规格等构造设置以及混凝土强度、钢材强度等材料性能变化在不同轴压力下对截面曲率和曲率延性的影响规律,相关性分析发现约束边缘H型钢是唯一与特征点曲率及曲率延性保持正相关的参数。该文分别提出竖波钢板组合剪力墙截面屈服、峰值、极限点曲率的简化计算方法并进行验证,证明了公式的准确性与适用性,可为竖波钢板组合剪力墙的弹塑性变形能力计算以及其损伤控制分析提供一定的理论支撑。