Numerical Investigation of Composite Shear Walls with Different Types of Steel and Concrete Materials as Boundary Elements

Q3 Engineering

Journal of Rehabilitation in Civil Engineering Pub Date : 2020-08-01 DOI:10.22075/JRCE.2020.17929.1343

A. Kheyroddin, M. Hajforoush, A. Doustmohammadi

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引用次数: 2

Abstract

The main purpose of this study is to numerically assess the effect of boundary elements with different types of steel and concrete materials on nonlinear performance of composite steel–reinforced concrete wall (CSRCW) by employing ABAQUS software. Two types of common steel profiles including box and I-shaped sections, located at the middle and extremities of the wall, were used to assess ultimate strength of the CSRCW. In addition, effects of concrete confinement on boundary elements were investigated for fully and partially encasement degrees. Following this, steel materials with three yield stresses of 300, 400 and 500 MPa, and concrete in two grades with compressive strengths of 30 and 40 MPa were considered. The theoretical results demonstrated that numerical models can predict the fracture zones similar to experimental observations where the failure modes of CSRCWs appeared to have ductile mechanisms. Based on the numerical outputs, the presence of I-shaped steel section in the middle of CSRCW participated to effectively distribute the stress throughout the shear wall, which was found to be 6.5% higher than that conventional shear wall. Furthermore, using steel boundary elements with higher yield strengths caused the highest amount of ultimate strength for the CSRCW to be 397.1 kN.

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以不同型钢和混凝土材料为边界元的组合剪力墙数值研究

本研究的主要目的是利用ABAQUS软件，数值评价不同型钢和混凝土材料的边界元对钢-钢筋混凝土组合墙(CSRCW)非线性性能的影响。采用位于墙体中部和末端的两种常见钢型材，包括箱形和工字形截面，来评估CSRCW的极限强度。此外，还研究了混凝土约束对边界元的完全和部分约束程度的影响。在此基础上，考虑了屈服应力分别为300、400、500 MPa的钢材和抗压强度分别为30、40 MPa的混凝土两种等级。理论结果表明，数值模型可以预测出与实验观测相似的断裂区域，在实验观测中，CSRCWs的破坏模式表现出延性机制。数值结果表明，CSRCW中部工字型钢截面的存在有效地参与了整个剪力墙的应力分布，比常规剪力墙高6.5%。采用屈服强度较高的钢边界元，可使CSRCW的最大极限强度达到397.1 kN。

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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来源期刊

Journal of Rehabilitation in Civil Engineering Engineering-Building and Construction

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

12 weeks