«Previous Article|Table of Contents|Next Article»

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

Issue:

2020年04期

Page:

52-59

Research Field:

Publishing date:

Info

Title:

Analysis on Influence Factors of Assembled Cross-ribbed Steel Plate Shear Wall

Author(s):

ZHENG Hong;  XU Xiao-dong;  WANG Wei;  ZHANG Min

(School of Civil Engineering, Chang'an University, Xi'an 710061, Shaanxi, China)

Keywords:

assembled cross-ribbed steel plate shear wall;  cross-ribbed grid;  embedded steel plate height thickness ratio;  hysteretic performance;  parameter analysis

PACS:

TU973.2

DOI:

10.19815/j.jace.2019.07057

Abstract:

The assembled cross-ribbed steel plate shear wall structure was proposed, the finite element analysis method was used to establish the finite element model of shear wall test of longitudinal and transverse multi-ribbed steel plate, and the validity and reliability of the modeling method was verified. The finite element model of cross-ribbed steel plate shear wall was established, the embedded steel plate height thickness ratio, multi-ribbed steel plate grid size were selected for variable parameters analysis, and the hysteretic curve, viscous damping coefficient, skeleton curve and stiffness degradation of each series of specimens were compared. The influence of geometric parameters of embedded steel plate wall on the hysteretic performance of cross-ribbed steel plate shear wall was analyzed, and the reasonable range of two parameters was given. The results show that when the height thickness ratio of the embedded steel plate λ≥ 500, the energy dissipation capacity, lateral bearing capacity and ductility of the test specimen increase significantly with the decrease of the height thickness ratio of the embedded steel plate. When λ<500, the above performance improvement is not obvious, and the recommended value of the embedded steel plate height thickness ratio λ is 500-600. The grid size of cross ribs has a significant effect on the hysteretic performance of specimens. The performance of the specimen increases with the decrease of the grid size of cross rib, and the increasing range is positively related to the decreasing range of the grid size. It is suggested that the number of cross-ribbed grid ribs should be less than or equal to 5×5.

References:

[1] SHEKASTEHBAND B,AZARAXSH A,SHOWKATI H.Experimental and Numerical Study on Seismic Behavior of LYS and HYS Steel Plate Shear Walls Connected to Frame Beams Only[J].Archives of Civil and Mechanical Engineering,2017,17(1):154-168.
[2]GUO H C,LI Y L,LING G,et al.Experimental Study of Cross Stiffened Steel Plate Shear Wall with Semi-rigid Connected Frame[J].Journal of Constructional Steel Research,2017,135:69-82.
[3]SIGARIYAZD M A,JOGHATAIE A,ATTARI N K A.Analysis and Design Recommendations for Diagonally Stiffened Steel Plate Sheer Walls[J].Thin-walled Structures,2016,103:72-80.
[4]ALAVI E,NATEGHI F.Experimental Study on Diagonally Stiffened Steel Plate Shear Walls with Central Perforation[J].Journal of Constructional Steel Research,2013,89:9-20.
[5]陈国栋.钢板剪力墙结构性能研究[D].北京:清华大学,2002.
CHEN Guo-dong.The Investigation to Structural Behavior of Steel Plate Shear Walls[D].Beijing:Tsinghua University,2002.
[6]陈国栋,郭彦林.非加劲板抗剪极限承载力[J].工程力学,2003,20(2):49-54.
CHEN Guo-dong,GUO Yan-lin.Ultimate Shear-carrying Capacity of Unstiffened Panels[J].Engineering Mechanics,2003,20(2):49-54.
[7]陈国栋,郭彦林,范 珍,等.钢板剪力墙低周反复荷载试验研究[J].建筑结构学报,2004,25(2):19-26,38.
CHEN Guo-dong,GUO Yan-lin,FAN Zhen,et al.Cyclic Test of Steel Plate Shear Walls[J].Journal of Building Structures,2004,25(2):19-26,38.
[8]曹春华,郝际平,杨 丽,等.钢板剪力墙弹塑性分析[J].建筑结构,2007,32(10):53-56.
CAO Chun-hua,HAO Ji-ping,YANG Li,et al.Elasto-plastic Analysis of Steel Plate Shear Walls[J]Building Structure,2007,32(10):53-56.
[9]陈国栋,郭彦林.十字加劲钢板剪力墙的抗剪极限承载力[J].建筑结构学报,2004,25(1):71-78.
CHEN Guo-dong,GUO Yan-lin.Ultimate Shear-carrying Capacity of Steel Plate Shear Wall with Cross Stiffeners[J].Journal of Building Structures,2004,25(1):71-78.
[10]郭彦林,陈国栋,缪友武.加劲钢板剪力墙弹性抗剪屈曲性能研究[J].工程力学,2006,23(2):84-91,59.
GUO Yan-lin,CHEN Guo-dong,MIAO You-wu.Elastic Buckling Behavior of Steel Plate Shear Wall with Cross or Diagonal Stiffeners[J].Engineering Mechanics,2006,23(2):84-91,59.
[11]曹春华.斜加劲钢板剪力墙性能研究[D].西安:西安建筑科技大学,2008.
CAO Chun-hua.The Investigation to Behavior Diagonal Stiffened Steel Plate Shear Walls[D].Xi'an:Xi'an University of Architecture & Technology,2008.
[12]王迎春,郝际平,李 峰,等.钢板剪力墙力学性能研究[J].西安建筑科技大学学报:自然科学版,2007,39(2):181-186.
WANG Ying-chun,HAO Ji-ping,LI Feng,et al.Study on Mechanical Property of Steel Plate Shear Walls[J]Journal of Xi'an University of Architecture & Technology:Natural Science Edition,2007,39(2):181-186.
[13]聂建国,朱 力,樊健生,等.钢板剪力墙抗震性能试验研究[J].建筑结构学报,2013,34(1):61-69.
NIE Jian-guo,ZHU Li,FAN Jian-sheng,et al.Experimental Research on Seismic Behavior of Steel Plate Shear Walls[J].Journal of Building Structures,2013,34(1):61-69.
[14]王 威.盖板加强斜加劲薄钢板墙性能研究[D].西安:长安大学,2018.
WANG Wei.Study on Performance of Cover-plate Stiffening Thin Plate Shear Wall[D].Xi'an:Chang'an University,2018.
[15]郑 宏,张 敏,王嘉政,等.盖板加强斜加劲钢板剪力墙受力性能[J].建筑科学与工程学报,2019,36(2):48-55.
ZHENG Hong,ZHANG Min,WANG Jia-zheng,et al.Force Performance of Cover-plate Diagonal Stiffening Steel Plate Shear Wall[J].Journal of Architecture and Civil Engineering,2019,36(2:)48-55.
[16]王先铁,林麟珲,宋文俊,等.竖向闭口槽钢加劲钢板剪力墙在非均匀压剪作用下的屈曲性能[J].建筑科学与工程学报,2017,34(6):51-58.
WANG Xian-tie,LIN Lin-hui,SONG Wen-jun,et al.Buckling Behavior of Steel Plate Shear Wall Stiffened by Vertical Closed Channel Stiffeners Under Non-uniform Pressure and Shear Load[J].Journal of Architecture and Civil Engineering,2017,34(6):51-58.
[17]于金光,郝际平.半刚性连接钢框架-非加劲钢板剪力墙结构性能研究[J].土木工程学报,2012,45(8):74-82.
YU Jin-guang,HAO Ji-ping.Study on the Behavior of Semi-rigid Connection Steel Frames with Unstiffened Steel Plate Share Wall Structure[J].China Civil Engineering Journal,2012,45(8):74-82.
[18]郝际平,郭宏超,解 崎,等.半刚性连接钢框架-钢板剪力墙结构抗震性能试验研究[J].建筑结构学报,2011,32(2):33-40.
HAO Ji-ping,GUO Hong-chao,XIE Qi,et al.Seismic Performance of Semi-rigid Composite Steel Frame with Steel Plate Shear Walls[J].Journal of Building Structures,2011,32(2):33-40.

Memo

Memo:

-

Common functions

Last Update: 2020-07-29