Study on interior beam–column joint sub-assemblage under bi-directional loading using finite element analysis

Shashikant Mahadev Nagargoje, Milinda Ashok Mahajan
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Abstract

Purpose The purpose of this paper is to study the shearing performance under bi-directional loading of an interior beam–column joint (BCJ) sub-assemblage using the finite element analysis (FEA) tool (midas fea), validated in this research. Design/methodology/approach The BCJ can be defined as an essential part of the column that transfers the forces at the ends of the members connected to it. The members of the rigid jointed plane frame resist external forces by developing twisting moment, bending moment, axial force and shear force in the frame members. On the type of joints, the response to the action of lateral loads depends on reinforced concrete (RC) framed structures. The joint is considered rigid if the angle between the members remains unchanged during the structural deformation. This work examined the shear deformation, load displacement and strength of a non-seismically detailed internal concentric RC joint using non-linear FEA. The bi-directional loading imposes the oblique compression zone on one joint corner. This joint core’s oblique compression strut mechanism differs significantly from that under unidirectional loading. The numerical results are compared with experimental results in this study, with the data published in the literature. Findings Numerical analysis results show that, in the comparative study of numerical and experimental values, the FEA tool predicts the behaviour of the RC BCJ well. The discrepancy between the experimental and numerical results amounts to 6 to 12% end displacement of the beam, 7% resultant joint shear force, 4.23% column bar strain and 0.70% hoop strain. Originality/value The current code of practice describes the joint sub-assemblage behaviour along the single axis individually. In the non-orthogonal system, the superposition of the two axes for joint space results in overlapping the stresses and, hence, the formation of the oblique strut. This may result in a reduction in the joint capacity under bi-directional loading. The behaviour must be explored in depth, and an attempt is made for further exploration.
利用有限元分析研究双向荷载下的内部梁柱连接分段组装
设计/方法/途径BCJ 可定义为柱的重要组成部分,用于传递与之相连的构件两端的力。刚性连接平面框架的构件通过在框架构件中产生扭转力矩、弯曲力矩、轴向力和剪切力来抵抗外力。钢筋混凝土(RC)框架结构对横向荷载作用的响应取决于连接类型。如果构件之间的夹角在结构变形过程中保持不变,则认为连接是刚性的。本研究利用非线性有限元分析法研究了非抗震内部同心 RC 接头的剪切变形、荷载位移和强度。双向荷载在一个连接角上施加了斜压区。该接头核心的斜压缩支撑机制与单向加载下的机制有很大不同。数值分析结果表明,在数值和实验值的对比研究中,有限元分析工具很好地预测了 RC BCJ 的行为。实验结果与数值结果之间的差异为 6% 至 12% 的梁端位移、7% 的接头剪力、4.23% 的柱杆应变和 0.70% 的箍筋应变。在非正交系统中,接头空间的两轴叠加会导致应力重叠,从而形成斜支撑。这可能会导致双向荷载下的连接能力降低。必须对这一行为进行深入探讨,并尝试进一步探索。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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