Restraint mechanism and bearing capacity calculation of steel-concrete composite square columns with internal spiral bars

被引：0

作者：

Zhou J. ^{[1
]}

Chen Z. ^{[1
,2
]}

Zhou C. ^{[3
]}

Jing C. ^{[4
]}

机构：

[1] College of Civil Engineering and Architecture, Guangxi University, Nanning

[2] College of Architecture and Civil Engineering, Nanning University, Nanning

[3] School of Civil and Environmental Engineering, Ningbo University, Ningbo

[4] College of Civil Engineering and Architecture, Guangxi University of Science and Technology, Liuzhou

来源：

Jianzhu Jiegou Xuebao/Journal of Building Structures | 2022年 / 43卷 / 11期

关键词：

axial compression test; bearing capacity; enhance effectiveness; restraint mechanism; spiral bars; steel-concrete composite square column;

D O I：

10.14006/j.jzjgxb.2021.0281

中图分类号：

学科分类号：

摘要：

In order to reveal the restraint mechanism of steel-concrete composite columns with spiral bars, and clarify the influence of design parameters such as the spacing of spiral bars, the diameter of spiral bars and the ratio of diameter to width of spiral bars on the restraint strengthening effect of composite columns, 30 specimens of steel-concrete composite square columns confined with spiral bars, including 15 angle steel specimens and 15 steel tube specimens, were tested under axial compression. The failure process of specimens was observed, the mechanism of constraint strengthening was revealed, the influence of various parameters on axial compression behavior of the specimens was analyzed, and the unified formulas for calculating the axial compression bearing capacity of composite columns were proposed. The test results show that the built-in spiral bars can effectively improve the restraint arch effect of square angle steel skeleton or steel tube on the core concrete, and improve the bearing capacity and deformation performance of composite columns, but has no obvious effect on stiffness. The ductility of composite columns can be further improved by increasing the volume reinforcement ratio of spiral bars, and the bearing capacity of composite columns can be improved most significantly by increasing the diameter width ratio of spiral bars, followed by reducing the spacing of spiral bars and increasing the diameter of spiral bars. The improvement degree of the bearing capacity slows down with the increase of the amounts of spiral bars, and the improvement effect of the built-in spiral bars on the bearing capacity of angle steel reinforced concrete columns is significantly better than that of concrete-filled steel tube columns. Combined with the constraint model and Mander’s theory of confined concrete, the formulas established in this paper can accurately calculate the axial bearing capacity of steel-concrete composite square columns confined with spiral bars. © 2022 Science Press. All rights reserved.

引用

页码：235 / 246+265

共 19 条

[1]

ZHANG Wenfu, DU Juan, DONG Qinghui, Et al., Experimental and theoretical research on mechanical behavior of angle reinforced high-strength concrete short columns subjected to eccentric compression, Journal of Building Structures, 34, pp. 252-258, (2013)

[2]

WEI Jiangang, LUO Xia, OU Zhijing, Et al., Experimental study on axial compressive behavior of circular UHPC filled high-strength steel tube short columns, Journal of Building Structures, 41, 11, pp. 16-28, (2020)

[3]

YU Zhiwu, HE Sasa, Experimental study on square concrete-filled tubular steel tube columns with insideconstraints under axial loads, Journal of Harbin Institute of Technology, 39, pp. 9-12, (2007)

[4]

HE Zhenqiang, CAI Jian, CHEN Xing, Investigation of behavior of square CFT stub columns with binding bars under axial loads, Building Structure, 36, 8, pp. 49-53, (2006)

[5]

CHEN Yong, ZHANG Yaochun, Experimental study and finite element analysis of square stub columns with tensile sheets of concrete-filled thin-walled steel tube, Journal of Building Structures, 27, 5, pp. 23-29, (2006)

[6]

DING F X, FANG C J, BAI Y, Et al., Mechanical performance of stirrup-confined concrete-filled steel tubular stub columns under axial loading, Journal of Constructional Steel Research, 98, pp. 146-157, (2014)

[7]

WANG Y Y, YANG Y L, ZHANG S M., Static behaviors of reinforcement-stiffened square concrete-filled steel tubular columns, Thin-Walled Structures, 58, pp. 18-31, (2012)

[8]

ZHANG Wenfu, JI Jing, LU Huawei, Et al., Behavior of angle reinforced concrete stub column under axial compression, Journal of Building Structures, 33, 4, pp. 121-127, (2012)

[9]

KIM H G, KIM M H, CHO N G, Et al., Experimental study on the compressive strength of yLRC composite columns, Journal of Korean Society of Steel Construction, 21, 5, pp. 545-552, (2009)

[10]

HWANG H J, EOM T S, PARK H G, Et al., Axial load and cyclic lateral load tests for composite columns with steel angles, Journal of Structural Engineering, 142, 5, (2016)

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