Numerical Analysis on Seismic Behavior of Steel Tubular Column-Shear Wall Transformation Nodes

Liang Hu; Ziming Yang; Xu Zhan; Ju Chen

doi:10.13206/j.gjgS23072702

Volume 39 Issue 9

Sep. 2024

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Liang Hu, Ziming Yang, Xu Zhan, Ju Chen. Numerical Analysis on Seismic Behavior of Steel Tubular Column-Shear Wall Transformation Nodes[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(9): 24-33. doi: 10.13206/j.gjgS23072702

Citation:

Liang Hu, Ziming Yang, Xu Zhan, Ju Chen. Numerical Analysis on Seismic Behavior of Steel Tubular Column-Shear Wall Transformation Nodes[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(9): 24-33. doi: 10.13206/j.gjgS23072702

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Numerical Analysis on Seismic Behavior of Steel Tubular Column-Shear Wall Transformation Nodes

doi: 10.13206/j.gjgS23072702

1. Institute of Structural EngineeringCollege of Civil Engineering and Architecture, Zhejiang University, Hangzhou 310058, China;
2. DongFang Boiler Group Co., Ltd., Chengdu 610000, China;
3. School of Automation and Information Engineering, Sichuan University of Science&Engineering, Zigong, Sichuan 643000, China

Received Date: 2023-07-27
Available Online: 2024-09-19

Abstract

Abstract

This study investigates the seismic performance of steel columns with different heights of concrete core fill under the combined action of axial compression and low-cycle reversed loading. The comparison between finite element modeling and experimental results is employed to validate the seismic performanceaccuracy of finite element modeling method. The fundamental parameters studied in the finite element model include the height of the core concrete, core concrete strength, steel material strength of the outer steel tube, axial load ratio, and the diameter-to-thickness ratio of the members, among others, all of which have a significant impact on the seismic performance of steel columns. The finite element analysis primarily focuses on hysteresis loops, skeleton curves, initial stiffness, stiffness degradation curves, and energy dissipation capacity. The following findings were obtained: Firstly, the height of the core concrete significantly influences the seismic performance of steel columns. Steel columns with lower concrete fill heights exhibit lower peak loads and failure displacements due to the smaller volume of concrete fill. As the concrete height increases from 0.25 times the column height to 0.5 times the column height, both peak loads and failure displacements increase significantly, along with a notable increase in the total number of cyclic loading cycles. This underscores the importance of considering concrete filling height in the design of steel columns to ensure adequate seismic performance. Secondly, the influence of the strength of the core concrete and steel material on seismic performance is relatively minor. High-strength concrete and steel do not significantly increase the initial stiffness of steel columns. This suggests that within a certain range, different concrete and steel materials can be chosen without a substantial impact on seismic performance. However, practical engineering still requires the selection of appropriate materials based on specific strength and stiffness requirements. Finally, an increase in the axial load ratio and the diameter-to-thickness ratio of members can enhance seismic performance to some extent, particularly in terms of energy dissipation capacity. Increasing the axial load ratio improves the load-carrying capacity of steel columns, while increasing the diameter-to-thickness ratio enhances their stiffness, thereby improving their seismic performance. Therefore, practical design considerations should comprehensively account for take these two parameters into account to optimize the seismic performance of steel columns. In summary, this study, through a detailed parameter analysis, elucidates the significant impact of core concrete height on the seismic performance of steel columns and provides a robust basis for the design and optimization of steel column structures.
- steel tubular column,
- concrete,
- seismic performance,
- numerical analysis

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References(27)

References

[1]	Pan X Z, Qiao S F, Li H, et al. Seismic behaviour of a new type of external hoop assembled joint for RC frame-added layer hybrid structure[J]. Structures, 2021, 32:170-193.
[2]	Sivandi-Pour A, Gerami M, Kheyroddin A. Uniform damping ratio for non-classically damped hybrid steel concrete structures[J]. International Journal of Civil Engineering, 2016, 14:1-11.
[3]	Griffis L G. Some design considerations for composite-frame structures[J]. Engineering Journal, AISC, 1986,23(2):59-64.
[4]	Gustavo P M, Wight K J. Seismic response of exterior RC columnto-steel beam connections[J]. Journal of Structural Engineering,2000, 126(10):1113-1121.
[5]	Nguyen X H, Nguyen Q H, Le D D, et al. Experimental study on seismic performance of new RCS connection[J]. Structures, 2017(9):53-62.
[6]	Papageorgiou A V, Gantes C J. Equivalent uniform damping ratios for linear irregularly damped concrete/steel mixed structures[J]. Soil Dynamics and Earthquake Engineering, 2011, 31(3):418-430.
[7]	Papageorgiou A V, Gantes C J. Equivalent modal damping ratiosfor concrete/steel mixed structures[J]. Computers&Structures,2010, 88(19/20):1124-1136.
[8]	Huang W, Qian J, Zhou Z, et al. An approach to equivalent damping ratio of vertically mixed structures based on response error minimization[J]. Soil Dynamics and Earthquake Engineering, 2015, 72:119-128.
[9]	Pan Z, Si Q, Zhou Z, et al. Experimental and numerical investigations of seismic performance of hybrid joints with bolted connections[J]. Journal of Constructional Steel Research, 2017, 138:867-876.
[10]	Pan X Z, Li H, Chao H, et al. Hysteretic behavior of a new type of outsourcing hybrid joint[J]. Structures, 2022, 40:88-108.
[11]	Kiani A, Kheyroddin A, Kafi M A, et al. Non-linear study of the method of transition in mixed concrete/steel structures[J/OL]. Soil Dynamics and Earthquake Engineering, 2023, 170[2023-03-28]. https://doi.org/10.1016/j.soildyn.2023.107925.
[12]	Bahri F, Kafi M A, Kheyroddin A. Full-scale experimental assessment of new connection for columns in vertically mixed structures[J/OL]. The Structural Design of Tall and Special Buildings, 2019, 28(12)[2019-05-29].https://doi.org/10.1002/tal.1629.
[13]	Hwang H J, Eom T S, Park H G, et al. Cyclic loading test for beam-column connections of concrete-filled U-shaped steel beamsand concrete-encased steel angle columns[J/OL]. Journal of Structural Engineering, 2015, 141(11)[2015-01-10].https://doi.org/10.1061/(ASCE)ST.1943-541X.000124.
[14]	宗钟凌,曹双寅,张皓,等.混凝土框架顶部钢结构加层连接节点抗震性能试验研究[J].建筑结构学报, 2011, 32(7):127-132.
[15]	范重,柴会娟,陈巍,等.钢管柱-钢筋混凝土框架转换节点设计研究[J].工程力学,2020,37(6):65-78.
[16]	Gao J Y, Nie X, Ding R, et al. Experimental study on seismic performance of a new transfer joint in the steel-concrete vertical hybrid structure[J/OL]. Journal of Constructional Steel Research, 2020, 174[2020-08-18].https://doi.org/10.1016/j.jcsr.2020.106259.
[17]	高劲洋,聂鑫,丁然,等.钢管柱-混凝土框架非下插转换节点抗震性能试验研究[J].建筑结构学报, 2023, 44(2):119-128.
[18]	Chen J, Yang Z M, Hu L, et al. Behavior of CFRP confined circular CFST columns reinforced with internal latticed steel angles under seismic loading[J/OL]. Journal of Constructional Steel Research, 2023, 208[2023-07-01]. https://doi.org/10.1016/j.jcsr.2023.108033.
[19]	韩林海.钢管混凝土结构[M]. 3版.北京:科学出版社,2000.
[20]	Xu F, Wang J, Chen J, et al. Load-transfer mechanism in angleencased CFST members under axial tension[J]. Engineering Structures, 2019, 178:162-178.
[21]	Yang Z M, Chen J, Wang F Y, et al. Seismic performance of circular concrete-filled steel tube columns reinforced with inner latticed steel angles[J/OL]. Journal of Constructional Steel Research, 2023,205[2023-03-27]. https://doi.org/10.1016/j.jcsr.2023.107908.
[22]	张劲,王庆扬,胡守营,等. ABAQUS混凝土损伤塑性模型参数验证[J].建筑结构,2008(8):127-130.
[23]	Sheehan T, Dai X H, Chan T M, et al. Structural response of concrete-filled elliptical steel hollow sections under eccentric compression[J]. Engineering Structures, 2012, 45:314-323.
[24]	Liu F Q, Wang Y Y, Chan T M. Behaviour of concrete-filled cold-formed elliptical hollow sections with varying aspect ratios[J]. Thin-Walled Structures, 2017, 110:47-61.
[25]	Wang J, Chen J, Qiu W J, et al. Analysis of CFRP-confinedCFST columns reinforced with steel angles under axial compression[J/OL]. Journal of Constructional Steel Research, 2022, 199[2022-10-30].https://doi.org/10.1016/j.jcsr.2022.107644.
[26]	Yin F, Xue S D, Cao W L, et al. Experimental and analytical study of seismic behavior of special-shaped multicell composite concrete-filled steel tube columns[J/OL]. Journal of Structural Engineering, 2020, 146(1)[2019-10-28]. https://doi.org/10.1061/(ASCE)ST.1943-541X.0002442.
[27]	Chen Z H, Dong S H, Du Y S. Experimental study and numerical analysis on seismic performance of FRP confined high-strength rectangular concrete-filled steel tube columns[J/OL]. Thin-Walled Structures,2021,162[2021-02-22]. https://doi.org/10.1016/j.tws.2021.107560.