|Table of Contents|

Comparative study on shear capacity calculation method for shear walls with CFST columns(PDF)

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

Issue:
2023年04期
Page:
97-106
Research Field:
建筑结构
Publishing date:

Info

Title:
Comparative study on shear capacity calculation method for shear walls with CFST columns
Author(s):
ZHU Qian JIA Xinyu LIU Jinye NI Zhaoyang ZHAO Junhai
(School of Civil Engineering, Chang'an University, Xi'an 710061, Shaanxi, China)
Keywords:
shear wall CFST column shear capacity softened strut-and-tie model unified strength theory
PACS:
TU398.2
DOI:
10.19815/j.jace.2022.04045
Abstract:
In order to study the applicability of different mechanical models in calculating the shear capacity of shear walls with concrete-filled steel tubular(CFST)columns, the empirical formulas and theoretical models deduced by domestic and foreign scholars were summarized. Various calculation methods were established based on the softened strut-and-tie model, unified strength theory and building codes at home and abroad. Then the performance of theoretical models and relevant building codes in predicting the shear capacity of such composite walls were compared and analyzed. Parametric studies were carried out to investigate the effects of axial compression ratio, aspect ratio, width thickness ratio and material properties on the calculation results. Finally, the accuracy and applicability of various mechanical models were validated by comparing with experimental data. The results show that the design methods of most standard models are generally lower than the experimental values, while the unified strength theory and the softened strut-and-tie model are relatively accurate. Meanwhile, the proposed formulas with softened strut-and-tie model not only can fully consider the contribution of each wall component, but also the calculation error is basically controlled within 20%. Moreover, under the premise of changing individual parameter, the calculated values by the softened strut-and-tie model are in good agreement with the test data. The analysis results can reasonably describe the shear mechanism and provide a theoretical basis for the optimum design of shear walls with CFST columns.

References:

[1] SHIN H M,LEE H D,SHIN K J.Shaking table test and analysis of reinforced concrete frame with steel shear wall with circular opening and slit damper[J].International Journal of Steel Structures,2018,18(4):1420-1430.
[2]ZHOU J,FANG X D,YAO Z Q.Mechanical behavior of a steel tube-confined high-strength concrete shear wall under combined tensile and shear loading[J].Engineering Structures,2018,171:673-685.
[3]徐培福,黄吉锋,陈富盛.近50年剪力墙结构震害及其对抗震设计的启示[J].建筑结构学报,2017,38(3):1-13.
XU Peifu,HUANG Jifeng,CHEN Fusheng.Earthquake damages to shear wall structure in last fifty years and seismic design enlightenment[J].Journal of Building Structures,2017,38(3):1-13.
[4]王 威,刘格炜,苏三庆,等.波形钢板剪力墙及组合墙抗剪承载力研究[J].工程力学,2019,36(7):197-206,226.
WANG Wei,LIU Gewei,SU Sanqing,et al.Research on the shear bearing capacity of corrugated steel plate shear wall and composite wall[J].Engineering Mechanics,2019,36(7):197-206,226.
[5]陈怀亮,卢中强,张大长,等.基于抗剪机构和破坏模式的RC剪力墙极限承载力分析[J].南京工业大学学报(自然科学版),2006,28(3):65-70.
CHEN Huailiang,LU Zhongqiang,ZHANG Dachang,et al.Study on ultimate strength of RC shear wall based on shear resistant mechanism and failure modes[J].Journal of Nanjing Tech University(Natural Science Edition),2006,28(3):65-70.
[6]李红运,傅剑平,姚佳琳.考虑边缘构件剪力墙抗震抗剪承载力计算[J].工业建筑,2019,49(11):64-71.
LI Hongyun,FU Jianping,YAO Jialin.Calculation for shear capacity of shear walls with boundary elements[J].Industrial Construction,2019,49(11):64-71.
[7]鲁懿虬,黄 靓.基于试验数据的带端柱或翼缘钢筋混凝土剪力墙抗剪承载力评估和分析[J].建筑结构,2019,49(9):92-98.
LU Yiqiu,HUANG Liang.Evaluation and analysis of shear capacity of shear capacity of barbell-shaped or flanged reinforced concrete walls based on experimental data[J].Building Structure,2019,49(9):92-98.
[8]吴函恒,周天华,陈军武,等.装配式钢框架-预制混凝土抗侧力墙结构受剪承载力分析[J].工程力学,2016,33(6):107-113.
WU Hanheng,ZHOU Tianhua,CHEN Junwu,et al.The shear bearing capacity of steel frame-concrete lateral-resistance-wall fabricated structure[J].Engineering Mechanics,2016,33(6):107-113.
[9]方小丹,孙孝明,韦 宏.钢管高强混凝土剪力墙受剪性能试验研究[J].建筑结构学报,2018,39(11):82-93.
FANG Xiaodan,SUN Xiaoming,WEI Hong.Experimental study on shear behavior of shear walls with steel tube-confined high-strength concrete[J].Journal of Building Structures,2018,39(11):82-93.
[10]高丹盈,尤培波,汤寄予,等.钢管混凝土边框钢纤维混凝土剪力墙受剪承载力计算[J].建筑结构学报,2018,39(6):10-20.
GAO Danying,YOU Peibo,TANG Jiyu,et al.Calculation method for shear capacity of steel fiber reinforced concrete shear wall with concrete filled steel tubular columns[J].Journal of Building Structures,2018,39(6):10-20.
[11]初明进,冯 鹏,叶列平.冷弯薄壁型钢混凝土剪力墙受剪承载力计算模型[J].建筑结构学报,2011,32(9):107-114.
CHU Mingjin,FENG Peng,YE Lieping.Analytical model for predicting shear strength of cold-formed thin-walled steel reinforced concrete shear walls[J].Journal of Building Structures,2011,32(9):107-114.
[12]朱 倩,蒋永杰,岳旭鹏,等.钢管RPC边框密肋复合剪力墙抗剪性能[J].建筑科学与工程学报,2020,37(5):142-150.
ZHU Qian,JIANG Yongjie,YUE Xupeng,et al.Shear behavior of multi-ribbed composite shear walls with RPC filled steel tubular columns[J].Journal of Architecture and Civil Engineering,2020,37(5):142-150.
[13]韩林海,杨有福.现代钢管混凝土结构技术[M].北京:中国建筑工业出版社,2004.
HAN Linhai,YANG Youfu.Modern concrete filled steel tube structural technology[M].Beijing:China Architecture & Building Press,2004.
[14]钱稼茹,崔 瑶,方小丹.钢管混凝土柱受剪承载力试验[J].土木工程学报,2007,40(5):1-9.
QIAN Jiaru,CUI Yao,FANG Xiaodan.Shear strength tests of concrete filled steel tube columns[J].China Civil Engineering Journal,2007,40(5):1-9.
[15]HWANG S J,LEE H J.Analytical model for predicting shear strengths of exterior reinforced concrete beam-column joints for seismic resistance[J].ACI Structural Journal,1999,96(5):846-857.
[16]HWANG S J,FANG W H,LEE H J,et al.Analytical model for predicting shear strength of squat walls[J].Journal of Structural Engineering,2001,127(1):43-50.
[17]HWANG S J,LEE H J.Strength prediction for discontinuity regions by softened strut-and-tie model[J].Journal of Structural Engineering,2002,128(12):1519-1526.
[18]YU M H.Unified strength theory and its applications[M].Berlin:Springer,2004.
[19]混凝土结构设计规范:GB 50010—2010[S].北京:中国建筑工业出版社,2011.
Code for design of concrete structures:GB 50010—2010[S].Beijing:China Architecture & Building Press,2011.
[20]Building code requirements for structural concrete and commentary:ACI 318-14[S].Washington DC:ACI,2014.
[21]Eurocode 2:Design of concrete structures:EN 1992-1-1[S].Brussels:European Committee for Standardization,2001.
[22]Design of concrete structures:CAN A23.3-04[S].Canada:Canadian Standards Association,2004.
[23]The standard for structure calculation of steel reinforced concrete structures:AIJ 2001[S].Tokyo:Architectural Institute of Japan,2001.
[24]曹万林,王 敏,王绍合,等.矩形钢管混凝土边框组合剪力墙及筒体结构抗震研究[J].工程力学,2008,25(增1):58-70.
CAO Wanlin,WANG Min,WANG Shaohe,et al.Aseismic research of composite shear wall and core walls with rectangular concrete filled steel tube columns[J].Engineering Mechanics,2008,25(S1):58-70.

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Last Update: 2023-07-01