«Previous Article|Table of Contents|Next Article»

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

Issue:

2019年04期

Page:

47-54

Research Field:

Publishing date:

Info

Title:

Wind Resistance of Large-span Steel Box Arch-corrugated Steel-truss Composite Beam Arch Bridge

Author(s):

TU Jun¹;  WANG Yu-yin²; 3;  LIU Yong-jian⁴;  LIU Chang-yong²; 3

1.Shenzhen Municipal Design&Research Institute Co,Ltd.,Shenzhen 518029,Guangdong,China; 2.Key Laboratory of Structures Dynamic Behavior and Control of Ministry of Education,Harbin Institute of Technology,Harbin 150090,Heilongjiang,China;3.Key Laboratory of Smart Prevention and Mitigation of CivilEngineering Disasters of Ministry of Industry and Information Technology,Harbin Institute of Technology,Harbin 150090,Heilongjiang,China;

Keywords:

arch bridge;  wind resistance;  full bridge aeroelastic;  wind tunnel test;  acceleration

PACS:

TU398

DOI:

-

Abstract:

In order to study the wind resistance performance of the steel box arch-corrugated steel-truss composite beam arch bridge used in the Shenzhen Houhai Park cross-lake bridge, a full bridge aeroelastic model was designed and fabricated according to the ratio of 1:100 on the premise of ensuring similar Froude number, Cauchy number and density to the real bridge. The arch rib and primary beam were fabricated using steel to achieve similar stiffness. ABS garment was placed on outer of the arch rib and primary beam to ensure geometric similarity. Weight was added to ensure mass similarity of the arch rib and primary beam. The stiffness of hanger was simulated by the customized spring. The agreement of dynamic characteristics between the test model and the real bridge was verified by finite element calculation. The wind tunnel test of the full bridge aeroelastic model in terrain C and uniform flow filed was conducted to measure the acceleration responses of the arch rib and primary beam under different wind yaw angles(0°, 30°, 60°, 90°)and different wind attack angles(-3°, 0°, 3°). The results show that the wind yaw angle has a significant influence on the acceleration of the arch rib and primary beam. The larger the yaw angle is, the lower the acceleration response is. The wind attack angle has an insignificant influence on the acceleration response of the arch rib and primary beam. The vortex induced vibration of the arch rib and primary beam is not observed in the turbulent flow field, while it occurs in the uniform flow field. No flutter occurs when the test wind speed exceeds the flutter critical wind speed calculated by the code of Wind-resistant Deisgn Specification for Highway Bridges.

References:

[1] 项海帆,葛耀君,朱乐东,等.现代桥梁抗风理论与实践[M].北京:人民交通出版社,2005.
XIANG Hai-fan,GE Yao-jun,ZHU Le-dong,et al.Modern Theory and Practice on Bridge Wind Resistance[M].Beijing:China Communications Press,2005.
[2]葛耀君.大跨度拱式桥抗风[M].北京:人民交通出版社股份有限公司,2014.
GE Yao-jun.Wind Resistance of Long Span arch Bridges[M].Beijing:China Communications Press Co.,Ltd.,2014.
[3]黄 超.大跨度拱桥空气动力特性风洞试验研究[D].重庆:重庆大学,2005.
HUANG Chao.Wind Tunnel Test Research on Aerodynamic Characteristics of Long Span Arch Bridge[D].Chongqing:Chongqing University,2005.
[4]阎卫国.超窄悬索桥抗风稳定性研究及风振响应控制[D].武汉:武汉理工大学,2008.
YAN Wei-guo.Research on Wind-resistant Stability and Vibration Control Measures of Narrow Width Suspension Bridge[D].Wuhan:Wuhan University of Technology,2008.
[5]徐洪涛.山区峡谷风特性参数及大跨度桁梁桥风致振动研究[D].成都:西南交通大学,2009.
XU Hong-tao.Research of Wind Characteristic Parameters and Wind-induced Vibration of Long Span Bridge with Truss Girder in Mountainous Area[D].Chengdu:Southwest Jiaotong University,2009.
[6]王承启.大跨度钢桁架拱桥风振研究[D].重庆:重庆大学,2011.
WANG Cheng-qi.Investigation on Wind-induced Vibration of Long-span Steel Trussed Arch Bridges[D].Chongqing:Chongqing University,2011.
[7]DIANA G,FIAMMENGHI G,BELLOLI M,et al.Wind Tunnel Tests and Numerical Approach for Long Span Bridges:The Messina Bridge[J].Journal of Wind Engineering and Industrial Aerodynamics,2013,122:38-49.
[8]DIANA G,YAMASAKI Y,LARSEN A,et al.Construction Stages of the Long Span Suspension Izmit Bay Bridge:Wind Tunnel Test Assessment[J].Journal of Wind Engineering and Industrial Aerodynamics,2013,123:300-310.
[9]LARSEN A,LAROSE G L.Dynamic Wind Effects on Suspension and Cable-stayed Bridges[J].Journal of Sound and Vibration,2015,334:2-28.
[10]CHEYNET E,JAKOBSEN J B,SNAEBJORNSSON J.Buffeting Response of a Suspension Bridge in Complex Terrain[J].Engineering Structures,2016,128:474-487.
[11]NUNEZ G J Z,LOREDO-SOUZA A M,ROCHA M M,et al.Aerodynamic Behavior of a Cable-stayed Bridge Section Composed by Inclined Parallel Decks[J].Journal of Wind Engineering and Industrial Aerodynamics,2018,173:156-170.
[12]HUI M C H,LARSEN A,XIANG H F.Wind Turbulence Characteristics Study at the Stonecutters Bridge Site:Part Ⅰ — Mean Wind and Turbulence Intensities[J].Journal of Wind Engineering and Industrial Aerodynamics,2009,97(1):22-36.
[13]HUI M C H,LARSEN A,XIANG H F.Wind Turbulence Characteristics Study at the Stonecutters Bridge Site:Part Ⅱ:Wind Power Spectra,Integral Length Scales and Coherences[J].Journal of Wind Engineering and Industrial Aerodynamics,2009,97(1):48-59.
[14]BULJAC A,KOZMAR H,POSPISIL S,et al.Aerodynamic and Aeroelastic Characteristics of Typical Bridge Decks Equipped with Wind Barriers at the Windward Bridge-deck Edge[J].Engineering Structures,2017,137:310-322.
[15]PERMATA R,ANDIKA M G,HAKIM N,et al.Wind Resistant Design of Ngarai Sianok Bridge in Bukittinggi,West Sumatera-Indonesia[J].Procedia Engineering,2017,171:1214-1221.
[16]KIM Y M,KWAY Y H,CHOI M S,et al.Wind Engineering on the New Millennium Bridge in South Korea[J].Procedia Engineering,2011,14:1472-1479.
[17]MA C,DUAN Q,LI Q,et al.Aerodynamic Characteristics of a Long-span Cable-stayed Bridge Under Construction[J].Engineering Structures,2019,184:232-246.
[18]白 桦,李 宇,李加武,等.钢桁架悬索桥颤振稳定性能研究[J].振动与冲击,2013,32(4):90-95.
BAI Hua,LI Yu,LI Jia-wu,et al.Flutter Stability of a Steel Truss Girder Suspension Bridge[J].Journal of Vibration and Shock,2013,32(4):90-95.
[19]王 凯,廖海黎,刘 君.山区峡谷大跨钢桁梁桥抗风特性试验研究[J].振动与冲击,2014,33(19):169-174.
WANG Kai,LIAO Hai-li,LIU Jun.Wind Resistance Tests for Long-span Steel Truss Bridges Across Gorges of Mountainous Area[J].Journal of Vibration and Shock,2014,33(19):169-174.

Memo

Memo:

-

Common functions

Last Update: 2019-07-26