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浙江大学学报(工学版)
JOURNAL OF ZHEJIANG UNIVERSITY (ENGINEERING SCIENCE)
Civil Engineering     
Effect of aerodynamic optimization to across-wind response of  super tall buildings
WANG Lei,LIANG Shu guo,WANG Ze kang,ZHANG Zheng wei
1. School of Civil Engineering,Henan Polytechnic University,Jiaozuo 454000,China;
2. School of Civil and Architectural Engineering, Wuhan University, Wuhan 430072,China;
3. Arup International Consultants (Shanghai) Limited Company,Shanghai 200031,China
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Abstract  

Wind tunnel tests of multi degree of freedom (MDOF) aero elastic model were conducted in order to analyze the influence of aerodynamic modifications on across wind response of super highrise buildings with square section. The across wind displacements of the models with various chamfering ratio, rounding ratio, openings and roughness were measured. Results showed that the vortex induced vibration (VIV) displacements were significantly decreased when the chamfering ratio was larger than 5% or the rounding ratio was larger than 15%. Under these conditions, the VIV RMS displacements were almost linear with reduced wind speed. The response level decreased with increasing chamfering ratio or rounding ratio, which means the possibility of vortex induced resonance phenomena was decreased. The setting of the specific rough can reduce the amplitude of the vibration response of the vortex by more than 20%.The openings can make the vortex vibration response amplitude decrease, especially when the opening is located at the middle of the model. In summary,aerodynamic optimization is an efficient way to control the vortex induced vibration of super tall buildings.

Published: 23 July 2016
CLC:  TU 312  
  TU 972  
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Cite this article:

WANG Lei,LIANG Shu guo,WANG Ze kang,ZHANG Zheng wei. Effect of aerodynamic optimization to across-wind response of  super tall buildings. JOURNAL OF ZHEJIANG UNIVERSITY (ENGINEERING SCIENCE), 2016, 50(7): 1239-1246.

URL:

http://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2016.07.003     OR     http://www.zjujournals.com/eng/Y2016/V50/I7/1239


超高层建筑横风向风振局部气动外形优化

为了研究局部气动措施对方截面超高层建筑横风向风振的控制效果,开展大量的多自由度气弹模型风洞实验,测量模型在多种切角率、圆角率、粗糙条及开洞方式下的横风向风致位移响应,对横风向位移进行对比分析.结果表明:当切角率大于5%或圆角率大于15%时,横风向风致位移响应显著降低,位移均方根随折算风速的变化曲线接近直线而不再呈倒“V”字形,说明涡激共振发生的可能性得到了有效抑制|切角率或圆角率越大,横风向位移响应的减小幅度越显著;特定粗糙条的设置可以使涡振响应幅值降低20%以上;通风洞不论是垂直于来流还是平行来流,都会使涡振响应幅值减小,且洞口在中上部时的效果最佳.整体来看,局部气动外形控制措施具有显著的抗风优化效果.

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