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

Issue:

2022年02期

Page:

36-43

Research Field:

防灾减灾工程

Publishing date:

Info

Title:

Damping Design of Semi-floating Main Girder Concrete-filled Steel Tubular Arch Bridge with Viscous Damper

Author(s):

PENG Yi-hua¹; 2; 3;  MAO Li-min²

(1. School of Management Science and Engineering,Guangxi University of Finance and Economics, Nanning 530007, Guangxi, China; 2. Guangxi Communications Design Group Co., Ltd., Nanning 530029, Guangxi, China; 3. School of Civil Engineering, Central South University, Changsha 410075, Hunan, China)

Keywords:

concrete-filled steel tubular arch bridge;  damping design;  nonlinear dynamic time history analysis;  viscous damper;  semi-floating main girder

PACS:

TU318

DOI:

10.19815/j.jace.2021.04060

Abstract:

In order to study the parameter selection and damping effect of viscous damper for long-span semi-floating main girder half through concrete-filled steel tubular arch bridge, taking a half through concrete-filled steel tubular arch bridge with a calculated span of 320 m as the engineering background, the finite element model was established by MIDAS/Civil software. Based on the analysis of dynamic characteristics, the damping scheme of viscous damper was proposed. Based on the nonlinear dynamic time history analysis method, the parameter selection and damping effect of viscous damper were studied. The results show that the longitudinal floating vibration mode of semi-floating main girder half through concrete-filled steel tubular arch bridge appears earlier, and the vibration mode takes a significant proportion in the mass. The allowable longitudinal displacement of the beam end and the damping force that the damper connecting members can bear should be considered in the selection of viscous damper parameters. For the same damping index, the maximum longitudinal displacement response of the main beam end decreases nonlinearly with the increase of the damping coefficient, and the axial force of the damper increases almost linearly with the increase of the damping coefficient. When the damping index changes within the range of 0.2-0.4, the larger the damping index is, the larger the optional range of damping coefficient meeting the requirements of beam end displacement and damping force is. After setting viscous damper, the longitudinal bridge displacement response of beam end decreases significantly, and the longitudinal bridge displacement of arch crown increases. Except that the axial force of arch rib at the vault decreases slightly, the axial force, shear force and bending moment at other places increase, but the absolute value of internal force response is small. The research results can provide reference for the seismic design of similar bridges.

References:

[1] 陈宝春,刘君平.世界拱桥建设与技术发展综述[J].交通运输工程学报,2020,20(1):27-41.
CHEN Bao-chun,LIU Jun-ping.Review of Construction and Technology Development of Arch Bridges in the World[J].Journal of Traffic and Transportation Engineering,2020,20(1):27-41.
[2]孙大斌,施 威,刘祥君.高速铁路异型拱桥抗震体系及抗震措施分析[J].铁道工程学报,2015,32(12):45-50.
SUN Da-bin,SHI Wei,LIU Xiang-jun.Analysis of Seismic Design System and Earthquake Resisting Methods of a High-speed Railway Heterotypic Arch Bridge[J].Journal of Railway Engineering Society,2015,32(12):45-50.
[3]LIN W H,CHOPRA A K.Earthquake Response of Elastic SDF Systems with Non-linear Fluid Viscous Dampers[J].Earthquake Engineering & Structure Dynamics,2002,31(9):1623-1642.
[4]GOEL R K.Seismic Response of Linear and Non-linear Asymmetric Systems with Non-linear Fluid Viscous Dampers[J].Earthquake Engineering & Structural Dynamics,2005,34(7):825-846.
[5]王志强,胡世德,范立础.东海大桥粘滞阻尼器参数研究[J].中国公路学报,2005,18(3):37-42.
WANG Zhi-qiang,HU Shi-de,FAN Li-chu.Research on Viscous Damper Parameters of Donghai Bridge[J].China Journal of Highway and Transport,2005,18(3):37-42.
[6]燕 斌,杜修力,韩 强,等.减隔震混合装置在独塔斜拉桥抗震设计中的应用[J].桥梁建设,2014,44(6):101-106.
YAN Bin,DU Xiu-li,HAN Qiang,et al.Application of Hybrid Seismic Mitigation and Isolation Device to Seismic Design of Single-pylon Cable-stayed Bridge[J].Bridge Construction,2014,44(6):101-106.
[7]李世渊,秦晶迪.某三跨斜拉桥纵向设置液体黏滞阻尼器阻尼系数优化[J].交通运输研究,2017,3(6):69-74.
LI Shi-yuan,QIN Jing-di.Damping Coefficient Optimization of Longitudinal Fluid Viscous Damper for a Three-tower Cable-stayed Bridge[J].Transport Research,2017,3(6):69-74.
[8]GUAN Z G,YOU H,LI J Z.An Effective Lateral Earthquake-resisting System for Long-span Cable-stayed Bridges Against Near-fault Earthquakes[J].Engineering Structures,2019,196(3):109345.
[9]GUO W,LI J Z,GUAN Z G.Shake Table Test on a Long-span Cable-stayed Bridge with Viscous Dampers Considering Wave Passage Effects[J].Journal of Bridge Engineering,2021,26(2):04020118.
[10]SU C,LI B M,CHEN T C,et al.Stochastic Optimal Design of Nonlinear Viscous Dampers for Large-scale Structures Subjected to Non-stationary Seismic Excitations Based on Dimension-reduced Explicit Method[J].Engineering Structures,2018,175:217-230.
[11]卢桂臣,胡雷挺.西堠门大桥液体粘滞阻尼器参数分析[J].世界桥梁,2005,33(2):43-45.
LU Gui-chen,HU Lei-ting.Analysis of Parametric Sensitivity of Fluid Viscous Dampers for Xihoumen Bridge[J].World Bridges,2005,33(2):43-45.
[12]郭志明,汪鸿鑫,叶爱君.设柔性中央扣的特大跨度悬索桥纵向抗震体系研究[J].桥梁建设,2020,50(1):38-43.
GUO Zhi-ming,WANG Hong-xin,YE Ai-jun.Longitudinal Anti-seismic System for Long-span Suspension Bridge with Flexible Central Buckle[J].Bridge Construction,2020,50(1):38-43.
[13]邬 都,李贞新.虎门二桥坭洲水道桥黏滞阻尼器参数研究[J].公路,2016(8):126-130.
WU Du,LI Zhen-xin.Study on Parameters of Viscous Damper for Nizhou Waterway Bridge of Humen No.2 Bridge[J].Highway,2016(8):126-130.
[14]刘振宇,李 乔,蒋劲松,等.南宁大桥粘滞阻尼器参数分析[J].桥梁建设,2007,37(4):25-28.
LIU Zhen-yu,LI Qiao,JIANG Jin-song,et al.Analysis of Parameters of Nanning Bridge Viscous Dampers[J].Bridge Construction,2007,37(4):25-28.
[15]童申家,李 纲,姜 浩.不同相位差地震作用下钢管混凝土拱桥减震研究[J].桥梁建设,2009,39(3):22-24,80.
TONG Shen-jia,LI Gang,JIANG Hao.Study of Seismic Mitigation of CFST Arch Bridge Under Action of Earthquake of Different Phase Differences[J].Bridge Construction,2009,39(3):22-24,80.
[16]李小珍,刘桢杰,辛莉峰,等.考虑行波效应的刚架系杆拱桥减隔震分析[J].铁道工程学报,2015,32(3):46-51.
LI Xiao-zhen,LIU Zhen-jie,XIN Li-feng,et al.Analysis of Seismic Isolation for Frame Tied Bridge Under the Effect of Traveling Wave[J].Journal of Railway Engineering Society,2015,32(3):46-51.

Memo

Memo:

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Common functions

Last Update: 2022-03-20