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《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:

2023年05期

Page:

69-77

Research Field:

建筑结构

Publishing date:

Info

Title:

Experimental study on shear behavior of new partially encased I-steel composite beams

Author(s):

XIN Li¹;  LIU Yuan¹;  YAO Yifan²;  HUANG Hua²;  GAO Yue²

(1. China Northwest Architecture Design and Research Institute Co., Ltd, Xi'an 710018, Shaanxi, China; 2. School of Civil Engineering, Chang'an University, Xi'an 710061, Shaanxi, China)

Keywords:

new partially encased I-steel composite beam;  shear behavior;  experimental test;  bearing capacity;  calculation method

PACS:

TU398

DOI:

10.19815/j.jace.2021.12124

Abstract:

In order to increase the utilization rate of steel and improve the shear behavior of composite beams, a new type of partially encased I-steel composite beam was proposed. Experimental study on shear behavior of four new composite beams and a contrast I-steel beam under static load was carried out with stud arrangement, shear span ratio and concrete filling amount as parameters, and “force-displacement control” loading method was adopted. The failure mode, shear-rotation curve, shear-strain curve and bearing capacity of the new composite beam and the contrast I-steel beam in the stress process were compared and analyzed. The results show that the composite beam with shear span ratio 1.6≤λ≤2.0 occurs shear compression failure, and the shear span area has the through main oblique cracks. The composite beam with shear span ratio 1.15 occurs tilting pressure failure. Multiple compression short columns are formed in the shear span area, and the concrete is peeled off in large area. When the shear span ratio is reduced from 1.6 to 1.15, the ultimate bearing capacity is increased by 31.8%. The shear capacity of the new composite beam is 33.3% higher than that of the ordinary I-steel beam due to the existence of concrete. The existence of flange studs improves the combined action of composite beam section, so that the concrete can give full play to its compressive capacity. The ultimate shear capacity is increased by 5.8%-29.2%, and the ductility and stiffness of composite beams are also increased. Based on the experimental data and the structural characteristics of the new partially encased I-steel composite beam, the shear capacity calculation formula in the design specification of composite structures is adopted. The calculated values of the formula are in good agreement with the experimental values. The formula can provide some reference for structural design in practical engineering.

References:

[1] 郝际平,孙晓岭,薛 强,等.绿色装配式钢结构建筑体系研究与应用[J].工程力学,2017,34(1):1-13.
HAO Jiping,SUN Xiaoling,XUE Qiang,et al.Research and applications of prefabricated steel structure building systems[J].Engineering Mechanics,2017,34(1):1-13.
[2]曹 杨,陈沸镔,龙 也.装配式钢结构建筑的深化设计探讨[J].钢结构,2016,31(2):72-76.
CAO Yang,CHEN Feibin,LONG Ye.Discussion on the detailed design of fabricated steel structure building[J].Steel Construction,2016,31(2):72-76.
[3]Eurocode 4:design of composite steel and concrete structures — part 1-1:general rules and rules for buildings:EN 1994-1-1:2004[S].Brussels:CEN,1994.
[4]聂建国,王洪全.钢-混凝土组合梁纵向抗剪的试验研究[J].建筑结构学报,1997,18(2):13-19.
NIE Jianguo,WANG Hongquan.Experimental study on longitudinal splitting strength of composite steel-concrete beams[J].Journal of Building Structures,1997,18(2):13-19.
[5]聂建国,陈 林,肖 岩.钢-混凝土组合梁正弯矩区截面的组合抗剪性能[J].清华大学学报(自然科学版),2002,42(6):835-838.
NIE Jianguo,CHEN Lin,XIAO Yan.Composite shear behavior of steel-concrete composite beams under sagging moment[J].Journal of Tsinghua University(Science and Technology),2002,42(6):835-838.
[6]HOSSAIN K M A,MOL L,WHITE H D.Behaviour of thin walled composite beams and columns[C]//SHANMUGAM N E,RICHARD LIEW J Y,THEVENDRAN V.Proceedings of International Conference on Thin-walled Structures.Singapore:Elsevier,1998:321-328.
[7]LIANG Q Q,UY B,BRADFORD M A,et al.Ultimate strength of continuous composite beams in combined bending and shear[J].Journal of Constructional Steel Research,2004,60(8):1109-1128.
[8]胡夏闽,江雨辰,施 悦,等.部分外包混凝土简支组合梁受弯性能试验研究[J].建筑结构学报,2015,36(9):37-44.
HU Xiamin,JIANG Yuchen,SHI Yue,et al.Experimental study on flexural behavior of simply supported partially concrete encased composite beams[J].Journal of Building Structures,2015,36(9):37-44.
[9]江雨辰,胡夏闽,王建林.部分外包钢梁受力性能试验研究及有限元分析[J].建筑结构学报,2015,36(增1):343-348.
JIANG Yuchen,HU Xiamin,WANG Jianlin.Experimental investigation and finite element analysis on mechanical performance of partially concrete encased steel beams[J].Journal of Building Structures,2015,36(S1):343-348.
[10]HE J,LIU Y Q,CHEN A R,et al.Shear behavior of partially encased composite I-girder with corrugated steel web:experimental study[J].Journal of Constructional Steel Research,2012,77:193-209.
[11]HE J,LIU Y Q,LIN Z F,et al.Shear behavior of partially encased composite I-girder with corrugated steel web:numerical study[J].Journal of Constructional Steel Research,2012,79:166-182.
[12]HE J,LIU Y Q,CHEN A R,et al.Bending behavior of concrete-encased composite I-girder with corrugated steel web[J].Thin-walled Structures,2014,74:70-84.
[13]TSAVDARIDIS K D,D'MELLO C,HUO B Y.Experimental and computational study of the vertical shear behaviour of partially encased perforated steel beams[J].Engineering Structures,2013,56:805-822.
[14]JIANG Y C,HU X M,HONG W,et al.Experimental study and theoretical analysis of partially encased continuous composite beams[J].Journal of Constructional Steel Research,2016,117:152-160.
[15]WU K,LIN S Q,LIU X Y,et al.Experimental study on mechanical behavior of prefabricated PEC composite beams under cyclic loading[J].International Journal of Steel Structures,2020,20(3):725-741.
[16]杨明昌,罗文飞,王军杰,等.装配整体式混凝土梁受剪性能试验及有限元分析[J].混凝土,2021(2):110-114.
YANG Mingchang,LUO Wenfei,WANG Junjie,et al.Shear test and finite element analysis of assembled monolithic concrete beams[J].Concrete,2021(2):110-114.
[17]蒋丽忠,曾丽娟,孙林林.钢-混凝土连续组合梁腹板局部屈曲分析[J].建筑科学与工程学报,2009,26(3):27-31.
JIANG Lizhong,ZENG Lijuan,SUN Linlin.Local buckling analysis of web of continuous steel-concrete composite beam[J].Journal of Architecture and Civil Engineering,2009,26(3):27-31.
[18]赵倩倩,周学军,张 婷,等.新型外包钢与混凝土简支组合梁非线性有限元分析[J].建筑结构,2011,41(增1):1119-1123.
ZHAO Qianqian,ZHOU Xuejun,ZHANG Ting,et al.Nonlinear analysis on U-section steel-encased concrete composite beams[J].Building Structure,2011,41(S1):1119-1123.
[19]杜德润,孟德丽,蒋济同.新型外包钢-混凝土组合梁与普通钢-混凝土组合梁性能对比分析[J].工业建筑,2014,44(增):559-562,577.
DU Derun,MENG Deli,JIANG Jitong.Comparative analysis of behaviors of the new-type steel-encased concrete composite beams and the ordinary steel-concrete composite beams[J].Industrial Construction,2014,44(S):559-562,577.
[20]金属材料拉伸试验 第1部分:室温试验方法:GB/T 228.1—2010[S].北京:中国标准出版社,2010.
Metallic materials — tensile testing — part 1:method of test at room temperature:GB/T 228.1—2010[S].Beijing:Standards Press of China,2010.
[21]混凝土结构试验方法标准:GB/T 50152—2012[S].北京:中国建筑工业出版社,2012.
Standard for test methods of concrete structures:GB/T 50152—2012[S].Beijing:China Architecture & Building Press,2012.

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Last Update: 2023-09-01