«Previous Article|Table of Contents|Next Article»

长安大学学报（自然科学版）[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2022年6期

Page:

12-22

Research Field:

桥梁工程·交通基础设施智能化运维技术专栏

Publishing date:

Info

Title:

Calculation theory of tensile equivalent width in steel plate-concrete joints with shear connectors

Author(s):

CHENG Gao¹; 2;  LI Meng-fei¹;  WANG Peng-qi¹;  XIE Liang³;  HAN Shuai¹

(1. School of Highway, Chang’an University, Xi’an 710064, Shaanxi, China; 2. Xizang Tianlu Co, Ltd,Lasa 850000, Xizang, China; 3. Hunan Architectural Design Institute Group Co, Ltd,Changsha 410208, Hunan, China)

Keywords:

bridge engineering;  steel plate-concrete;  Winkler elastic foundation beam;  equivalent width;  tension joint;  joint stiffness;  finite element verification

PACS:

U441

DOI:

10.19721/j.cnki.1671-8879.2022.06.002

Abstract:

In order to study the reasonable arrangement of shear connectors and tensile theory of steel plate and concrete joints, a theoretical analysis model of steel plate-concrete joints with shear connectors based on Winkler elastic foundation beam theory was established. The steel plate was equivalent to the elastic foundation beam, and the shear connector was equivalent to the elastic foundation. Based on the plane section assumption and the internal force balance condition of the microelement, the differential equations of tensile load and joint deformation were established, and the effective working width and deformation characteristics of the joint under tension were obtained. Based on the principle of stress equivalence, the equivalent width of joints under tension was proposed and solved analytically. Through the calculation of the beam element finite element model of the tension joint, the rationality of the joint tension theory analysis assumption based on the Winkler elastic foundation beam theory was verified. Through the finite element calculation of plate-shell-solid element, the accuracy of the calculation method of working width, equivalent width and joint stiffness deduced by theory was verified. The results show that the vertical displacement of the steel plate with shear connectors shows a parabola distribution along the transverse direction, which accords with the basic assumption of the classical elastic foundation beam. The working width, equivalent width and tensile stiffness of the joint depend on the bending stiffness of the steel plate at the joint, the shear stiffness and density of the shear connector. The working width and equivalent width of the joint increase with the increase of the bending inertia moment of the steel plate section, and decrease with the increase of the shear stiffness of the shear connector. The tensile stiffness of the joint increases with the increase of the bending inertia moment of the steel plate section and the shear stiffness of the shear connector. The analytical formulas for calculating the tensile working width, equivalent width and tensile stiffness of joints are given.16 figs, 33 refs.

References:

[1] 彭 强.南京长江五桥钢壳混凝土桥塔足尺模型工艺试验 [J].桥梁建设,2019,49(3):46-50.
PENG Qiang.Full-scale model test of construction process for steel shell-concrete composite pylon of Fifth Changjiang River Bridge in Nanjing [J].Bridge Construction,2019,49(3):46-50.
[2]张喜刚,刘 高,高 原,等.中空型外壁钢板-混凝土组合桥塔塔柱承载力研究 [J].土木工程学报,2018,51(3):90-98.
ZHANG Xi-gang,LIU Gao,GAO Yuan,et al.Research on the bearing capacity of hollow concrete-filled steel exterior wall composite bridge tower column [J].China Civil Engineering Journal,2018,51(3):90-98.
[3]TAN Y L,ZHU B,YAN T Y,et al.Experimental study of the mechanical behavior of the steel-concrete joints in a composite truss bridge[J].Applied Sciences.2019,9(5):854.
[4]万 馨,高铃钰,陈 明,等.基于装配式交叉U型连接件的钢板混凝土组合剪力墙-钢梁节点性能有限元分析 [J].硅酸盐通报,2021,40(1):113-122,132.
WAN Xin,GAO Ling-yu,CHEN Ming,et al.Finite element analysis of performance of steel plate concrete composite shear wall-steel beam joint based on prefabricated cross U-shaped connector [J].Bulletin of the Chinese Ceramic Society,2021,40(1):113-122,132.
[5]GUO L,WANG J F,WANG W Q,et al.Seismic evaluation and calculation models of CFDST column blind bolted to composite beam joints with partial shear interaction [J].Engineering Structures,2019,196:109269.
[6]刘明虎,孙 鹏,胡广瑞,等.港珠澳大桥青州航道桥“中国结”形钢剪刀撑设计与施工 [J].桥梁建设,2016,46(1):81-87.
LIU Ming-hu,SUN Peng,HU Guang-rui,et al.Design and construction of “Chinese knot” style steel cross bracing for pylon of Qingzhou Ship Channel Bridge of Hong Kong-Zhuhai-Macao Bridge [J].Bridge Construction,2016,46(1):81-87.
[7]梅应华,朱大勇,严 瑾.混凝土主梁斜拉桥锚拉板式索梁锚固区受力性能研究 [J].世界桥梁,2019,47(1):26-31.
MEI Ying-hua,ZHU Da-yong,YAN Jin.Study of load bearing behavior of cable-girder anchorage zone of anchor tensile plate type for concrete main girder cable-stayed bridge [J].World Bridges,2019,47(1):26-31.
[8]伍子鸿.桁腹式组合桁梁桥的关键节点及其剪力滞效应研究[D].哈尔滨:哈尔滨工业大学,2015.
WU Zi-hong.Study on key joint and shear lag effect of steel-concrete composite truss bridge[D].Harbin:Harbin Institute of Technology,2015.
[9]PU Q H,BAI G L.Internal force distribution in steel-concrete composite structure for pylon of cable-stayed bridge [J].Journal of Southwest Jiaotong University(English Edition),2009,17(2):95-101.
[10]周绪红,张 茜,狄 谨,等.对称荷载作用钢锚板式钢-混组合索塔锚固体系传力机理 [J].中国公路学报,2012,25(6):60-67.
ZHOU Xu-hong,ZHANG Qian,DI Jin,et al.Load-transfer mechanism of steel-concrete composite cable-pylon anchorage system with steel anchor slab under symmetrical load [J].China Journal of Highway and Transport,2012,25(6):60-67.
[11]狄 谨,周绪红,游金兰,等.钢箱梁斜拉桥索塔锚固区的受力性能 [J].中国公路学报,2007,20(4):48-52.
DI Jin,ZHOU Xu-hong,YOU Jin-lan,et al.Mechanical property of cable-pylon anchorage zone of cable-stayed bridge with steel box girder [J].China Journal of Highway and Transport,2007,20(4):48-52.
[12]李 源,王凌波,刘 鹏,等.港珠澳大桥青州航道桥索塔结形撑安装精细化分析 [J].中国公路学报,2016,29(12):93-101.
LI Yuan,WANG Ling-bo,LIU Peng,et al.Delicate installation analysis of cross bracing of Qingzhou Channel Bridge in Hong Kong-Zhuhai-Macao Bridge [J].China Journal of Highway and Transport,2016,29(12):93-101.
[13]SU Q T,YANG G T,QIN F,et al.Investigation on the horizontal mechanical behavior of steel-concrete composite cable-pylon anchorage [J].Journal of Constructional Steel Research,2012,72:267-275.
[14]刘建军,王学敏.红水河特大桥钢牛腿-钢锚梁组合锚固结构设计研究 [J].中外公路,2016,36(6):127-133.
LIU Jian-jun,WANG Xue-min.Study on the design of combined anchorage structure of steel corbel and steel anchor beam of Hongshuihe Bridge[J].Journal of China & Foreign Highway,2016,36(6):127-133.
[15]肖 林,刘丽芳,卫 星,等.钢-混组合索塔锚固结构的力学行为及结构优化 [J].西南交通大学学报,2019,54(5):923-930,944.
XIAO Lin,LIU Li-fang,WEI Xing,et al.Mechanical behavior and structural optimization of steel-concrete composite cable-pylon anchor [J].Journal of Southwest Jiaotong University,2019,54(5):923-930,944.
[16]石雪飞,周军勇,胡 可,等.锚拉板式混凝土索梁锚固体系实桥试验研究 [J].桥梁建设,2016,46(3):11-16.
SHI Xue-fei,ZHOU Jun-yong,HU Ke,et al.Experimental study of anchor tensile plate cable anchorage system in concrete girder of actual bridge [J].Bridge Construction,2016,46(3):11-16.
[17]张 煜,阮 欣,石雪飞,等.斜拉桥钢-混锚板式索梁锚固区摩擦效应分析 [J].中南大学学报(自然科学版),2013,44(7):2982-2988.
ZHANG Yu,RUAN Xin,SHI Xue-fei,et al.Friction effects analysis of steel-concrete anchor plate in cable-beam anchorage zones of cable-stayed bridges [J].Journal of Central South University(Science and Technology),2013,44(7):2982-2988.
[18]YIN G A,DING F X,WANG H B,et al.Connection performance in steel-concrete composite truss bridge structures[J].Journal of Bridge Engineering.2017,22(3):4016126.
[19]LI Y J,LIU Y Q,WANG F H,et al.Load transfer mechanism of hybrid pylon joint with cells and bearing plates[J].Advances in Civil Engineering,2018:1-12.
[20]刘永健,王文帅,马印平,等.矩形钢管和矩形钢管混凝土T形不等宽受拉节点轴向刚度 [J].建筑科学与工程学报,2020,37(1):1-13.
LIU Yong-jian,WANG Wen-shuai,MA Yin-ping,et al.Axial stiffness of RHS and CFRHS T-joints with unequal width subjected to tension [J].Journal of Architecture and Civil Engineering,2020,37(1):1-13.
[21]MA Y P,LIU Y J,WANG K,et al.Axial stiffness of concrete filled rectangular steel tubular(CFRST)truss joints [J].Journal of Constructional Steel Research,2021,184:106820.
[22]程 高,刘永健,田智娟,等.PBL加劲型矩形钢管混凝土不等宽T型节点受拉性能 [J].长安大学学报(自然科学版),2015,35(3):83-90.
CHENG Gao,LIU Yong-jian,TIAN Zhi-juan,et al.Tensile behavior of PBL stiffened concrete-filled rectangular steel tubular unequal T-connections [J].Journal of Chang’an University(Natural Science Edition),2015,35(3):83-90.
[23]郑双杰,刘玉擎.开孔板连接件初期抗剪刚度试验 [J].中国公路学报,2014,27(11):69-75.
ZHENG Shuang-jie,LIU Yu-qing.Experiment of initial shear stiffness of perfobond connector [J].China Journal of Highway and Transport,2014,27(11):69-75.
[24]莫志鹏.PBL加劲型矩形钢管混凝土节点受拉性能研究 [D].西安:长安大学,2021.
MO Zhi-peng.Research on tensile properties of concrete-filled rectangular steel tubular joints stiffened with PBL [D].Xi’an:Chang’an University,2021.
[25]侯蓓蓓,刘永健,姜 磊,等.PBL加劲型矩形钢管混凝土支管受拉节点有效分布宽度 [J].建筑科学与工程学报,2017,34(6):116-126.
HOU Bei-bei,LIU Yong-jian,JIANG Lei,et al.Effective distribution width of tension joints in brace of rectangular concrete-filled steel tube stiffened with PBL [J].Journal of Architecture and Civil Engineering,2017,34(6):116-126.
[26]田智娟.PBL加劲型矩形钢管混凝土T型受拉节点力学性能研究[D].西安:长安大学,2014.
TIAN Zhi-juan.Research on mechanical properties of tension T-joints of rectangular concrete-filled steel tube stiffened with PBL[D].Xi’an:Chang’an University,2014.
[27]YANG Y,CHEN Y.Experimental study on mechanical behavior of PBL shear connectors [J].Journal of Bridge Engineering,2018,23(9):4018062.
[28]MA Y P,LIU Y J,MA T Y,et al.Flexural stiffness of rectangular hollow section(RHS)trusses [J].Engineering Structures,2021,239:112336.
[29]龙驭球.弹性地基梁的计算 [M].北京:人民教育出版社,1981.
LONG Yu-qiu.Calculation of elastic foundation beam [M].Beijing:People’s Education Press,1981.
[30]GARIFULLIN M,BRONZOVA M,PAJUNEN S,et al.Initial axial stiffness of welded RHS T-joints [J].Journal of Constructional Steel Research,2019,153:459-472.
[31]刘永健,刘君平,池建军.钢管混凝土界面抗剪粘结滑移力学性能试验 [J].广西大学学报(自然科学版),2010,35(1):17-23,29.
LIU Yong-jian,LIU Jun-ping,CHI Jian-jun.Shear bond behaviors at interface of concrete-filled steel tube [J].Journal of Guangxi University(Natural Science Edition),2010,35(1):17-23,29.
[32]刘永健,李 慧,张 宁,等.PBL加劲型矩形钢管混凝土界面粘结-滑移性能 [J].建筑科学与工程学报,2015,32(5):1-7.
LIU Yong-jian,LI Hui,ZHANG Ning,et al.Interface bond-slip performance of rectangular concrete-filled steel tube stiffened by PBL [J].Journal of Architecture and Civil Engineering,2015,32(5):1-7.
[33]程 高.PBL加劲型矩形钢管混凝土结构工作机理研究[D].西安:长安大学,2015.
CHENG Gao.Research on the mechanism of rectangular concrete-filled steel tube structure stiffened with PBL[D].Xi’an:Chang’an University,2015.

Memo

Memo:

-

Common functions

Last Update: 2022-12-20