[1]李 宇,冯 朴,李加武,等.超高桥塔的气弹模型风洞试验及其等效静力风荷载[J].建筑科学与工程学报,2024,41(02):96-105.[doi:10.19815/j.jace.2022.03069]
LI Yu,FENG Pu,LI Jiawu,et al.Aeroelastic model wind tunnel test and equivalent static wind load for superhigh bridge tower[J].Journal of Architecture and Civil Engineering,2024,41(02):96-105.[doi:10.19815/j.jace.2022.03069]
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超高桥塔的气弹模型风洞试验及其等效静力风荷载(PDF)
LI Yu,FENG Pu,LI Jiawu,et al.Aeroelastic model wind tunnel test and equivalent static wind load for superhigh bridge tower[J].Journal of Architecture and Civil Engineering,2024,41(02):96-105.[doi:10.19815/j.jace.2022.03069]
《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]
- 卷:
- 41卷
- 期数:
- 2024年02期
- 页码:
- 96-105
- 栏目:
- 桥隧工程
- 出版日期:
- 2024-03-30
文章信息/Info
- Title:
- Aeroelastic model wind tunnel test and equivalent static wind load for superhigh bridge tower
- 文章编号:
- 1673-2049(2024)02-0096-10
- Author(s):
- LI Yu, FENG Pu, LI Jiawu, FU Yao
- (School of Highway, Chang'an University, Xi'an 710064, Shaanxi, China)
- Keywords:
- superhigh bridge tower; aeroelastic model; wind tunnel test; gust loading factor; equivalent static wind load
- 分类号:
- U448.27
- 文献标志码:
- A
- 摘要:
- 为研究超高桥塔的气弹模型风洞试验方法及其等效静力风荷载,根据某实际工程中的超高桥塔建立了有限元模型,进行了动力特性计算,进而设计了相应的气弹模型,并开展了风洞试验。在此基础上,开展了超高桥塔风致振动的非线性时程计算,并基于阵风荷载因子法,对比了以位移、内力和应力为单一目标的超高桥塔的等效静力风荷载。结果表明:斜风作用下的桥塔风致振动比较显著,其影响随着风速的增大而愈加明显; 当风向角为75°~90°时,超高桥塔将在风速为35~50 m?s-1的区间发生顺桥向的侧弯涡振,但幅值较小; 基于应力的阵风荷载因子比基于位移或内力的阵风荷载因子更加稳定,这使得基于应力的等效静力风荷载要优于基于位移或内力的等效静力风荷载,比较适合于超高桥塔。
- Abstract:
- In order to study the wind tunnel test method and equivalent static wind load of the aeroelastic model of superhigh bridge towers, a finite element model was established based on a superhigh bridge tower in a practical project, and dynamic characteristics were calculated. Subsequently, a corresponding aeroelastic model was designed and wind tunnel tests were conducted. On the basis, nonlinear time-history calculations of wind induced vibration of superhigh bridge towers were carried out. Based on the gust load factor method, the equivalent static wind load of superhigh bridge towers with displacement, internal force, and stress as a single objective was compared. The results show that the wind-induced vibration of the bridge tower under the action of oblique wind is relatively significant, and its impact becomes more pronounced as the wind speed increases. When the wind direction angle is from 75° to 90°, the superhigh bridge tower will experience lateral bending vortex vibration along the bridge direction in the range of wind speed is from 35 m?s-1 to 50 m?s-1, but the amplitude is small. The gust load factor based on stress is more stable than the gust load factor based on displacement or internal force, which makes the equivalent static wind load based on stress superior to the equivalent static wind load based on displacement or internal force, making it more suitable for super high bridge towers.
参考文献/References:
[1] 付 曜.桥塔自立状态等效静力风荷载研究[D].西安:长安大学,2019.
FU Yao.Equivalent static wind load for free-standing pylon[D].Xi'an:Chang'an University,2019.
[2]KAREEM A.Fluctuating wind loads on buildings[J].Journal of the Engineering Mechanics Division,1982,108(6):1086-1102.
[3]SAIFUL ISLAM M,ELLINGWOOD B,COROTIS R B.Dynamic response of tall buildings to stochastic wind load[J].Journal of Structural Engineering,1990,116(11):2982-3002.
[4]KAWAI H.Vortex induced vibration of tall buildings[J].Journal of Wind Engineering and Industrial Aerodynamics,1992,41(1/2/3):117-128.
[5]李寿英,陈政清.超高层建筑风致响应及等效静力风荷载研究[J].建筑结构学报,2010,31(3):32-37.
LI Shouying,CHEN Zhengqing.Experimental and theoretical study on wind induced responses and effective static wind load on super-high-rise buildings[J].Journal of Building Structures,2010,31(3):32-37.
[6]吴海洋,梁枢果,陈政清,等.强风下方截面高层建筑横风向气动阻尼比研究[J].工程力学,2010,27(10):96-103.
WU Haiyang,LIANG Shuguo,CHEN Zhengqing,et al.Research on the aerodynamic damping ratios of square tall buildings in across-wind direction under strong wind[J].Engineering Mechanics,2010,27(10):96-103.
[7]曹会兰,全 涌,顾 明.矩形截面超高层建筑横风向气动阻尼的风洞试验研究[J].空气动力学学报,2014,32(3):351-359.
CAO Huilan,QUAN Yong,GU Ming.Wind tunnel test on across-wind aerodynamic damping of rectangular super-high-rise buildings[J].Acta Aerodynamica Sinica,2014,32(3):351-359.
[8]马文勇,周佳豪,郑德乾,等.塔冠对方形截面超高层建筑横风向基底弯矩的影响[J].建筑结构学报,2021,42(增2):466-472.
MA Wenyong,ZHOU Jiahao,ZHENG Deqian,et al.Effects of tower crown on across-wind base bending moment of square super high-rise buildings[J].Journal of Building Structures,2021,42(S2):466-472.
[9]韩 振,李 波,甄 伟,等.宽厚比为5的超高层建筑风荷载特性研究[J].哈尔滨工程大学学报,2022,43(2):196-202.
HAN Zhen,LI Bo,ZHEN Wei,et al.Wind load characteristics of the super-tall buildings with a side ratio of 5[J].Journal of Harbin Engineering University,2022,43(2):196-202.
[10]DAVENPORT A G.Gust loading factors[J].Journal of the Structural Division,1967,93(3):11-34.
[11]KASPERSKI M,NIEMANN H J.The L.R.C.(load-response-correlation)-method a general method of estimating unfavourable wind load distributions for linear and non-linear structural behaviour[J].Journal of Wind Engineering and Industrial Aerodynamics,1992,43(1/2/3):1753-1763.
[12]DAVENPORT A G.How can we simplify and generalize wind loads?[J].Journal of Wind Engineering and Industrial Aerodynamics,1995,54-55:657-669.
[13]KAREEM A,ZHOU Y.Gust loading factor-past,present and future[J].Journal of Wind Engineering and Industrial Aerodynamics,2003,91(12/13/14/15):1301-1328.
[14]柯世堂,葛耀君,赵 林,等.一致耦合方法的提出及其在大跨空间结构风振分析中的应用[J].中南大学学报(自然科学版),2012,43(11):4457-4463.
KE Shitang,GE Yaojun,ZHAO Lin,et al.Proposition and application of consistent coupling method in wind-induced response of long span structures[J].Journal of Central South University(Science and Technology),2012,43(11):4457-4463.
[15]YEO D,SIMIU E.High-rise reinforced concrete stru-ctures:database-assisted design for wind[J].Journal of Structural Engineering,2011,137(11):1340-1349.
[16]SIMIU E,YEO D.Advances in the design of high-rise structures by the wind tunnel procedure:conceptual framework[J].Wind and Structures,2015,21(5):489-503.
[17]PARK S,YEO D.Second-order effects on wind-induced structural behavior of high-rise steel buildings[J].Journal of Structural Engineering,2018,144(2):04017209.
[18]PARK S,SIMIU E,YEO D.Equivalent static wind loads vs.database-assisted design of tall buildings:an assessment[J].Engineering Structures,2019,186:553-563.
[19]李 宇,付 曜,李 琛.超高层建筑结构抗风性能研究[J].建筑科学与工程学报,2018,35(2):63-70.
LI Yu,FU Yao,LI Chen.Research on wind-resistant performance for super high-rise building[J].Journal of Architecture and Civil Engineering,2018,35(2):63-70.
[20]建筑结构荷载规范:GB 50009—2012[S].北京:中国建筑工业出版社,2012.
Load code for the design of building structures:GB 50009—2012[S].Beijing:China Architecture & Building Press,2012.
[21]公路桥梁抗风设计规范:JTG/T 3360-01—2018[S].北京:人民交通出版社,2019.
Wind-resistant design specification for highway bridges:JTG/T 3360-01—2018[S].Beijing:China Communications Press,2019.
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备注/Memo
- 备注/Memo:
-
收稿日期:2023-03-14
基金项目:国家自然科学基金项目(51808053); 陕西省自然科学基础研究计划项目(2023·JC-YB-438)
作者简介:李 宇(1982-),男,工学博士,副教授,E-mail:liyu@chd.edu.cn。
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