Numerical simulation of wind-induced vibration characteristics of square-section high-rise buildings

被引：0

作者：

Lu S.-S. ^{[1
,2
]}

Zhang Z.-F. ^{[1
,2
]}

Chen W.-L. ^{[1
,2
]}

机构：

[1] Key Lab of Smart Prevention and Mitigation of Civil Engineering Disasters of Ministry of Industry and Information Technology, Harbin Institute of Technology, Harbin

[2] Key Lab of Structures Dynamic Behavior and Control of the Ministry of Education, Harbin Institute of Technology, Harbin

来源：

Zhendong Gongcheng Xuebao/Journal of Vibration Engineering | 2021年 / 34卷 / 05期

关键词：

Flow field; Fluid-structure coupling; High-rise building; Numerical simulation; Vortex induced vibration;

D O I：

10.16385/j.cnki.issn.1004-4523.2021.05.004

中图分类号：

学科分类号：

摘要：

In this study, a square-section high-rise building with width to height ratio of 1:6 was regarded as the research object. The Navier-Stoke equation of incompressible viscous fluid is solved based on the RSM model by using the computational fluid software FLUENT. The vibration response of the structure was solved by Newmark-β method (connected by user-defined function of FLUENT), thus researching the wind-induced vibration of the structure characteristic. Then, the flow field around rigid static model and aeroelastic model was studied. The results showed an obvious phenomenon of displacement 'locking in' happened in high-rise buildings, which was in good agreement with the wind tunnel test results. In the velocity profiles, the change rule of displacement response was related to the average wind speed of the flow field. When the average wind speed was close to the locked wind speed, the displacement response of the structure was most obvious. With the increase of the wind speed, the structure presented first and second order wind-induced vibration respectively. The flow field around high-rise structures had obvious three-dimensional characteristics. Along the height of high-rise building, the development of vortex was unbalanced. The closer it was to the bottom, the shedding vortex was asymmetric, and the closer it was to the top, the shedding vortex was symmetric. And its change rule was related to the velocity distribution of the flow field. © 2021, Editorial Board of Journal of Vibration Engineering. All right reserved.

引用

页码：911 / 921

页数：10

共 13 条

[1] Saunders J W, Melbourne W H., Buffeting effects of upstream buildings‍[J], Wind Engineering, 1, pp. 593-606, (1980)
[2] Islam S M, Ellingwood B, Corotis R B., Dynamic response of tall buildings to stochastic wind loads, Journal of Structural Engineering, 116, 11, pp. 2982-3002, (1990)
[3] Kareem A., Dynamic response of high-rise buildings to stochastic wind loads, Journal of Wind Engineering & Industrial Aerodynamics, 42, 1-3, pp. 1101-1112, (1992)
[4] Quan Yong, GU Ming, Analytical method of across-wind response and equivalent static wind loads of high-rise buildings, Engineering Mechanics, 23, 9, pp. 84-88, (2006)
[5] Zhang J, Dalton C., Interactions of vortex-induced vibrations of a circular cylinder and a steady approach flow at a Reynolds number of 13000[J], Computers & Fluids, 25, 3, pp. 283-294, (1996)
[6] Xu Feng, Jinping Ou, Numerical simulation of unsteady flow around square cylinder and vortex-induced vibration, Journal of Southeast University(Natural Science Edition), 35, S1, pp. 35-39, (2005)
[7] Deng Jian, Ren Anlu, Zou Jianfeng, Numerical study of transverse galloping and vortex-induced vibrations of square cylinder, Journal of Zhejiang University (Engineer Science), 39, 4, pp. 595-599, (2005)
[8] Revuz J, Hargreaves D M, Owen J S., Numerical simulation of the dynamic wind loading on and response of tall buildings, 5th European & African Conference on Wind Engineering, (2009)
[9] (2014)
[10] Chen W L, Li H, Ou J P, Et al., Numerical simulation of vortex-induced vibrations of inclined cables under different wind profiles [J], Journal of Bridge Engineering, 18, 1, pp. 42-53, (2013)

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