横肋波纹钢板-钢管混凝土短柱轴压受力机理研究

横肋波纹钢板-钢管混凝土柱(CFHCST)是由四角方钢管与侧壁波纹钢板焊接形成的多腔体与混凝土组合而成。为研究其受力机理及轴力分配规律,本文采用ABAQUS建立了CFHCST的分析模型,并基于得到的试验数据验证了该模型的准确性。在此基础上,从构件的荷载-纵向应变曲线、各钢材组分的应力-应变曲线发展规律及混凝土的纵向应力分布等多方面进行了分析,同时评价了不同参数对其承载力、延性及承载力提高系数的影响。研究结果表明:波纹钢板几乎不承担轴向荷载,构件承载力的大小主要由核心混凝土和方钢管混凝土决定;构件截面的强约束区主要集中在核心混凝土的截面核心处以及方钢管角部;波纹钢板表面受力不均匀,波峰与波中处钢材均表现为双向受拉,且波峰对混凝土的约束效果最好。在结合现有规范以及有限元参数分析结果的基础上,建立了CFHCST承载力计算公式。公式计算结果偏于安全,可为工程设计提供参考。

核心钢管混凝土短柱轴压受力机理及设计方法研究

为研究核心钢管混凝土(CSTRC)短柱轴压受力机理及设计方法,完成了7个CSTRC柱和2个RC柱的轴压试验,采用有限元软件ABAQUS对CSTRC柱轴压全过程进行数值仿真。在试验验证的基础上,利用有限元模型研究了CSTRC柱的轴压机理和轴力分配规律。研究表明,核心钢管混凝土柱试件中,钢管对内部混凝土的约束作用明显,钢管外部混凝土对钢管的约束作用可以忽略,其承载力可按RC部分与钢管混凝土柱部分承载力进行线性叠加。根据有限元分析结果,提出了CSTRC柱中钢管混凝土部分的承载力发挥系数。本文成果可为CSTRC结构的设计和应用提供参考。

钢筋混凝土剪力墙拉压变轴力低周往复受剪试验研究

完成了截面纵筋率为3%,剪跨比为1.5的2片钢筋混凝土剪力墙拉压变轴力低周往复受剪试验。当剪力墙反复处于拉剪、压剪受力状态时,剪力墙在拉剪阶段屈服,在压剪阶段发生脆性受压破坏。当承受的拉力较小时剪力墙为大偏心受拉,斜裂缝处竖向和水平分布筋屈服;当承受的拉力较大时剪力墙为小偏心受拉,水平通缝处截面纵筋屈服。剪力墙受压时刚度大,端部纵筋受拉后再受压容易屈曲,因此其抗压剪承载力先于抗拉剪承载力达到峰值,抗压剪承载力因混凝土的受压脆性经过峰值点后迅速下降。与拉剪受力相比,剪力墙在压剪受力时的承载力高、变形小。剪力墙的抗拉剪、抗压剪承载力和抗压剪变形能力随目标轴力幅度的提高而下降。与定轴力受剪试验结果相比,剪力墙在拉压变轴力受剪时的抗拉剪承载力降低,抗压剪承载力未有显著变化。轴拉力不仅会降低剪力墙的抗剪承载力,还会加大剪力墙受拉、受压时抗剪承载力的差异,因此应控制底部剪力墙受拉,并控制墙体受拉水平。

传统铁箍墩接法加固底部糟朽木柱轴压试验

铁箍墩接是古建木柱柱根糟朽的一种传统加固方法。为探讨该方法的有效性,以故宫内某古建木柱为例,进行了试验研究。制作了1根完好木柱、3根铁箍墩接法加固木柱,开展了轴压试验,获得了木柱加固前后的承载力-变形曲线,以及延性、应变、刚度等参数,讨论了铁箍墩接法的加固机理。结果表明:传统铁箍法加固底部糟朽木柱后,由于铁箍对木柱的侧向约束作用,木柱的极限承载力可恢复约91.8%,延性性能可恢复约95.2%,水平极限应变恢复率约97.2%,竖向极限应变恢复率约84.1%,且加固木柱的刚度要大于完好木柱。由于铁箍材料与木材强度差别较大,使得加固后木柱的整体性能要低于完好木柱,因而加固效果有限。结果可为古建筑木结构的保护与维修提供理论参考。

Strength of circular concrete columns under concentric compression

An experimental study, in which six columns were loaded concentrically toinvestigate the behavior of reinforced normal strength and high strength circular columns underconcentric compression, is described. The concrete strengths of the columns were 30 MPa and 60 MPa.The primary variables considered were the concrete strength and the amount of transversereinforcement. Test results indicate that smaller hoop spacing provides higher column capacity andgreater strength enhancement in a confined concrete core of columns. For the same lateralconfinement, high strength concrete columns develop lower strength enhancement than normal strengthconcrete columns. Both the strength enhancement ratio (f'_(cc) /f'_(co)) and the column capacityratio (P_(test)/P_o) were observed to show linear increase variations with rho_s f_(yt)/f'_c incircular columns.

Bearing capacity of concrete filled bidirectional FRP tube subjected to axial compression

External confinement by fiber reinforced polymer (FRP) is an efficient technique to increase the bearing capacity and ductility of concrete. To better study the mechanical behavior of bidirectional FRP confined concrete, the yield criterion of bidirectional FRP is presented based on the static equilibrium condition in this paper, and a model for calculating the bearing capacity of bidirectional FRP confined concrete is established. The model can capture the character of bidirectional FRP confined concrete. Effects of the confinement effect coefficient, the unconfined concrete strength and the material properties of FRP on bearing capacity are analyzed. Results show that each parameter has different effects on the bearing capacity of bidirectional FRP confined concrete.