期刊检索

  • 2024年第56卷
  • 2023年第55卷
  • 2022年第54卷
  • 2021年第53卷
  • 2020年第52卷
  • 2019年第51卷
  • 2018年第50卷
  • 2017年第49卷
  • 2016年第48卷
  • 2015年第47卷
  • 2014年第46卷
  • 2013年第45卷
  • 2012年第44卷
  • 2011年第43卷
  • 2010年第42卷
  • 第1期
  • 第2期

主管单位 中华人民共和国
工业和信息化部
主办单位 哈尔滨工业大学 主编 李隆球 国际刊号ISSN 0367-6234 国内刊号CN 23-1235/T

期刊网站二维码
微信公众号二维码
引用本文:杨肖悦,秦玮峰,柯延宇,谢霁明.镂空双层幕墙对高层建筑结构风响应的影响[J].哈尔滨工业大学学报,2021,53(10):70.DOI:10.11918/202104029
YANG Xiaoyue,QIN Weifeng,KE Yanyu,XIE Jiming.Effects of porous double skin faade system on structural wind responses of tall buildings[J].Journal of Harbin Institute of Technology,2021,53(10):70.DOI:10.11918/202104029
【打印本页】   【HTML】   【下载PDF全文】   查看/发表评论  下载PDF阅读器  关闭
过刊浏览    高级检索
本文已被:浏览 1441次   下载 748 本文二维码信息
码上扫一扫!
分享到: 微信 更多
镂空双层幕墙对高层建筑结构风响应的影响
杨肖悦,秦玮峰,柯延宇,谢霁明
(浙江大学 建筑工程学院,杭州 310058)
摘要:
镂空双层幕墙以建筑节能与美学方面的突出优点日益得到建筑界与工程界的青睐。镂空层具有柔化建筑角部气流分离的作用,对控制高层建筑的风振响应也应产生有利影响。为此以一栋典型方形高层建筑的风振加速度和结构风荷载为例,通过详细的风洞试验研究了镂空双层幕墙的效果,重点研究镂空双层幕墙覆盖面积与覆盖位置的影响,同时考察了不同类别场地的影响。研究结果证实了镂空双层幕墙在抑制建筑横风向响应方面的有效性,特别是当镂空双层幕墙位于建筑物上部且覆盖至少1/6总高度时有效性更为显著。同时发现镂空双层幕墙的有效性随约化风速(无量纲参数)不同而有所变化。当约化风速<10.5时,覆盖建筑物上部1/3高度的镂空双层幕墙可使建筑物的加速度降低20%~30%。当约化风速>10.5时,风振加速度和结构风荷载则可以降低多达45%。这表明镂空双层幕墙不仅可以用于降低极端风下的结构设计风荷载,而且可用于改善建筑物在常遇风条件下的运营品质。风洞试验结果还表明,不同场地条件下镂空双层幕墙在减少横风向响应方面的效果基本类似。因此,在建筑优化设计中可以将镂空双层幕墙考虑为对现有建筑空气动力学优化方法的一个理想补充。
关键词:  高层建筑  镂空双层幕墙  气动优化  风洞试验  风荷载  风振加速度  结构风响应
DOI:10.11918/202104029
分类号:TU973
文献标识码:A
基金项目:国家自然科学基金(51578505)
Effects of porous double skin faade system on structural wind responses of tall buildings
YANG Xiaoyue,QIN Weifeng,KE Yanyu,XIE Jiming
(College of Civil Engineering and Architecture, Zhejiang University, Hangzhou 310058, China)
Abstract:
Due to the strengths of porous double skin faade (porous DSF) systems in building energy efficiency and architectural aesthetics, they have become increasingly popular in the architectural and engineering fields. Given the fact that porous DSF can soften the flow separation around building corners, it is expected that porous DSF systems should have the potential in controlling wind-induced structural responses. Therefore, a detailed wind tunnel study was conducted to investigate the effects of porous DSF on the wind-induced accelerations and structural wind loads of a typical square tall building, focusing on the influence of the porous DSF coverage area and its location. The performance of the porous DSF under different terrain conditions was also examined during the wind tunnel tests. Research results confirmed the effectiveness of the porous DSF in suppressing the across-wind responses of buildings, especially when the porous DSF located in the upper part of the building and covered at least 1/6 of the total height. It was also found that the effectiveness of the porous DSF varied with reduced wind velocity (a non-dimensional parameter). When the reduced wind velocity was lower than 10.5, the porous DSF system covering the upper 1/3 of the building height could reduce the building acceleration by 20% to 30%. When the reduced wind velocity was higher than 10.5, the building acceleration and structural wind loads could both be reduced by up to 45%. It suggests that porous DSF can not only be utilized to reduce the structural design wind loads in extreme wind events, but also be employed to improve the serviceability performance of the building in normal wind conditions. The wind tunnel tests for different terrain conditions revealed similar effects of porous DSF in reducing across-wind responses. Thus, porous DSF systems can be regarded as an ideal supplement to the existing aerodynamic approaches in building optimization design.
Key words:  tall buildings  porous double skin faade (porous DSF)  aerodynamic optimization  wind tunnel test  wind loads  wind-induced accelerations  structural wind responses

友情链接LINKS