不同自由端约束条件下双轴对称工字形截面悬臂梁的稳定性

对自由端侧向位移和扭转简支约束、自由端仅扭转约束和自由端仅简支扭转弹性约束条件下,双轴对称工字形截面悬臂梁的稳定性进行研究,并提出临界弯矩的计算公式。这一计算公式能够考虑悬臂梁长细比的变化,以及横向荷载作用点沿截面高度方向变化对其临界弯矩的影响。通过与有限元结果的比较可以发现,所提出的计算公式可以获得精度良好的临界弯矩值。     

销钉式防屈曲支撑性能试验研究

防屈曲耗能支撵(BRB)作为一种新型的支撑构件,具有良好的耗能减震作用,目前已广泛应用于一些实际工程.本文提出了一种新型防屈曲支撑——销钉式防屈曲支撑,该支撑耗能部分由全钢一字型内核和销钉组成,其特点在于构造简单、初始刚度高,小变形时起普通支撑作用,大变形时起耗能作用,比较适用于层间变形较小的混凝土等结构.制作了全钢、摩擦、钢铅组合和销钉式防屈曲支撑,通过拟静力试验,对比研究了4种防屈曲支撑的性能.结果表明:销钉式防屈曲支撑荷载-位移滞回曲线饱满,初始刚度较全钢防屈曲支撑提高将近80％,在较小变形时提供较大的初始刚度,在大变形时销钉断裂使防屈曲支撑进入屈服耗能状态.     

海控国际广场屈曲约束支撑应用研究

屈曲约束支撑具有良好的延性与滞回性,克服了传统支撑体系受压屈曲的缺点,具有良好的抗震性能,在高层建筑中逐渐应用.海控国际广场项目A座结构35 ～ 50层外框角部均使用屈曲约束支撑作为结构抗侧力耗能构件.通过介绍该工程中屈曲约束支撑的应用,对该类工程施工的常见难点问题的解决方法进行了分析.     

Seismic response of a 40‐storey buckling‐restrained braced frame designed for the Los Angeles region

This study utilized nonlinear response history analysis to compare the seismic demand on three variations of a 40‐storey buckling‐restrained braced frame designed for high seismic hazard in the Los Angeles region. The three designs were referred to as a ‘code‐based design’, based on the 2006 International Building Code, a ‘performance‐based design’, based on criteria published by the Los Angeles Tall Building Design Council (LATBSDC) and a ‘performance‐based design plus’, based on newly developed criteria from The Pacific Earthquake Engineering Research Center (PEER). The response history analysis utilized spectrum‐matched ground motions as well as simulated ground motions for the Puente Hills fault. The spectrum‐matched motions were selected from the Next Generation Attenuation of Ground Motions (NGA) database, which is largely composed of recorded motions and scaled to five hazard levels. The simulated ground motions were broadband signals generated from a moment magnitude (M_w) 7.15 scenario rupture of the Puente Hills fault for two near fault regions and exhibit long period energy content that significantly exceeds the uniform hazard spectrum. Structural performance was assessed in terms of exceedance of a safe inter‐storey drift ratio (IDR). It was seen that the simulated ground motions impose higher IDR demands on the structures than the spectrum‐matched NGA ground motions. Furthermore, the number of instances of exceedance of a safe IDR, considered for this study as IDR = 0.03, is substantially higher for the simulated ground motions, pointing to the importance of considering such motions in the collapse prevention of tall buildings on a site‐specific basis. Copyright © 2010 John Wiley & Sons, Ltd.     

航空复合材料短柱加筋板压缩性能试验研究

开展了航空复合材料短柱加筋板的轴向压缩试验。试验件的破坏形式主要包括壁板的撕裂、筋条的断裂和端部的压溃现象,试验过程中,壁板及筋条没有出现明显的脱粘现象。在试验加载初期,载荷-应变曲线呈线性一致的增加趋势,位移测量点的离面位移值基本保持在0 mm附近;当压缩载荷超过临界屈曲载荷时,载荷-应变曲线出现了明显的分岔现象,且离面位移值快速增加。复合材料短柱加筋板失稳后仍然具有后屈曲承载能力,但是该承载能力较小,当短柱加筋板发生失稳后,随着压缩载荷的增加,试验件会很快发生破坏。有限元仿真结果与试验结果较一致,仿真结果表明短柱加筋板主要发生了壁板的局部失稳。     

Effect of gusset connection configurations on frame–gusset interaction in steel buckling‐restrained braced frame

Although buckling restrained braces (BRBs) are commonly applied in seismic buildings to mitigate structural damage, their performance was often limited by rupture of the corner gusset connections due to additional frame action. This issue may be resolved by alternative gusset connections to mitigate the frame–gusset interaction. In this study, commonly used procedures for design of the traditional gusset connection are reviewed, followed by a case study on the effect of frame action on the structural behavior of these gusset connections in steel frames with BRBs. Inspired by these analysis, two different strategies, aiming at releasing frame–gusset shear interaction using sliding gusset connection or reducing normal interaction using dual gusset plates, are tried to mitigate the frame action effects. Finite element analysis is conducted on steel frame subassemblages with/without BRBs to examine the effect of different gusset connections on the structural behavior of these framing systems. It shows that the sliding gusset connection shows beneficial effect in reducing the frame action, having much smaller stress responses on the gusset interfaces, as well as smaller shear force and plastic responses on the framing system. Thus, it becomes a promising gusset connection for improved seismic performance of the steel framing system with brace‐type dampers.     

Seismic performance of corrugated steel plate concrete composite shear walls

In this paper, composite shear walls with different encased steel plates (flat, horizontal corrugated, and vertical corrugated) were tested and simulated by Abaqus to investigate the seismic behavior of corrugated steel plate concrete composite shear walls (SPCSWs). The failure characteristics, deformation and energy dissipation capacity, and stiffness and bearing capacity of the structures under low‐frequency cyclic load were analyzed, and indexes of the seismic performance were obtained. The formulas of the shear‐bearing capacity of steel plate concrete composite shear walls are suggested, and the shear‐sharing ratio of each member is obtained. According to the obtained results, corrugated steel plates can bond with concrete well, and the bearing capacity of the vertical corrugated SPCSW are higher than that of the horizontal corrugated SPCSW. Compared with flat SPCSW, corrugated SPCSW has higher initial stiffness and lateral stiffness, better ductility and energy dissipation ability, and the degradation of bearing capacity and stiffness is slower. The shear‐sharing ratio of a steel plate is larger than that of reinforced concrete in the flat SPCSW and the vertical corrugated SPCSW, the shear force shared by steel plate and reinforced concrete in horizontal corrugated SPCSW is basically the same.     

Seismic design and performance analysis of buckling‐restrained braced RC frame structures

Due to the stable hysteretic behavior, buckling‐restrained braces (BRBs) have been increasingly adopted in reinforced concrete (RC) frame structures to develop a dual structural system (BRB‐RCF). This study proposed an alternative strength‐based design approach that decomposes the dual BRB‐RCF system into two independent RC frame and BRB system using the BRB‐carrying story shear ratio. The design of RC frame is performed in an integrated manner by considering the BRB postyielding force demands. Three RC frames with five, 10, and 15 stories were employed as prototype structures, and seven story shear ratios ranging from 0.1 to 0.7 were used to generate a total of 21 structural modes. The material usage, maximum axial compression ratio of columns, and elastic interstory drift ratio were compared for different story shear ratios. Nonlinear dynamic analysis of the BRB‐RCFs subjected to 12 ground motions were carried out. The seismic response including the maximum interstory drift ratio, hysteretic energy dissipation ratio, and actual BRB‐carrying story shear ratio were systematically assessed for different design story shear ratios. Based on the considerations of material usage and seismic performance, it is suggested that the design BRB‐carrying story shear ratio should be in the range of 0.3 to 0.5.     

基于杆系离散单元法的单层网壳结构屈曲行为研究

离散单元法因适合处理大位移、非线性和非连续等问题而逐渐被应用于结构工程中,但采用离散单元法进行结构屈曲全过程分析还有待研究。为此,基于杆系离散单元法的基本理论和计算方法,提出离散元力控制法及离散元位移控制法,研究上述方法在结构弹性屈曲全过程分析中的特点及适用性,同时给出离散元位移控制法（力控制法不需要单独处理）对不同荷载工况的处理方法及离散元法在进行结构弹性屈曲分析时的计算流程。采用Fortran语言自编程序,对典型算例进行弹性屈曲全过程分析,与传统方法相比,该方法无需组集刚度矩阵,对几何非线性问题不需特殊处理即可模拟结构的屈曲行为,更具优越性,并通过结果对比,验证了离散单元法在单层网壳结构弹性失稳全过程分析中的有效性。     

方钢管混凝土中钢管和混凝土抗压强度研究

对于方钢管混凝土柱在轴压作用下的受力性能,国内外学者已经进行了大量的试验研究和理论分析,但常规轴压试验无法得到钢管和混凝土各自承担的轴压力。为此,提出了一种在方钢管混凝土柱试件上部设置轴力测量段的试验方法,用于直接测量轴压下方钢管混凝土柱中钢管和混凝土所承担的轴压力。通过对5个不同宽厚比的方钢管混凝土柱试件开展轴压试验,发现方钢管混凝土柱中混凝土的抗压强度与其对应的轴心抗压强度相近。将试验得到的钢管抗压强度与已有经验公式结果进行对比,发现已有经验公式可合理预测钢管的抗压强度,针对钢管的屈曲后行为和其他因素的影响需要展开更深入的研究。在试验结果的基础上,提出了方钢管混凝土柱的轴压承载力计算式,其计算结果与文献试验结果吻合良好。