具有复杂屋顶几何形状的低层建筑的空气动力学减缓

IF 2.2 Q2 CONSTRUCTION & BUILDING TECHNOLOGY
R. Al-Chalabi, A. Elshaer
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引用次数: 1

摘要

在强风事件中,建筑屋顶会受到高风升力(吸力)的影响,这通常会导致严重的屋顶部件损坏,甚至屋顶完全失效、飞溅的碎片和水入侵,从而导致内部损坏。典型的屋顶形状(如山墙和屋脊)通常使用规定规范和标准进行设计,以准确估计风事件期间影响屋顶的峰值荷载,用于设计目的。使用风洞测试和计算建模可以有效地检查复杂的屋顶几何形状,以提供风的定量评估,从而缩小设计备选方案的范围,并检查从缓解技术中获得的改进。在本研究中,使用大涡模拟(LES)对一座具有复杂屋顶形状的孤立低层建筑进行了检查,通过与风洞结果的验证,对风荷载预测进行了数值评估。这项研究提出了两种屋顶改造方案,使用添加到屋顶角落和山脊线的护栏来转移分离位置的水流,以减少风对屋顶的影响。目前的研究旨在1)评估具有复杂屋顶几何形状的孤立低层建筑在不同迎角下的风荷载;2)使用护栏、增加的拐角和脊线从空气动力学角度减轻屋顶,以减少风对屋顶的影响。验证表明,压力系数的平均值和均方根值与风洞结果吻合良好。研究结果表明,位于复杂屋顶几何形状的拐角和边缘的500mm高的女儿墙可以有效地降低29%的极端拐角吸力和5.6%的屋顶隆起。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Aerodynamic mitigation of low-rise building with complex roof geometry
During strong wind events, building roofs are subjected to high wind uplift forces (suctions), which often lead to severe roofing component damage, or even roof total failure, flying debris, and water intrusion, hence, interior damages. Typical roof shapes (e.g., gable and hip) are generally designed using provision codes and standards to accurately estimate peak load impacting the roofs during wind events for design purposes. Complex roof geometry can be efficiently examined using wind tunnel testing and computational modeling to provide quantitative assessment for wind to narrow down the design alternatives and to examine the improvement gained from mitigation techniques. In this study, an isolated low-rise building with a complex roof shape is examined using large eddy simulation (LES) to numerically assess wind load prediction by validating it with wind tunnel results. This study presents two roof modification scenarios using parapets added to roof corners and ridgelines to displace the flow from the separation locations to reduce the wind impact on the roof. The current study aims to 1) evaluate wind load on an isolated low-rise building with complex roof geometry for various angles of attack and 2) mitigate the roof aerodynamically using parapets, added corners, and ridgeline to reduce the wind impact on the roof. The validation shows that both the mean and RMS of the pressure coefficients are in good agreement with the wind tunnel results. The research results suggest that parapets with 500 mm height located at the corner and edges of complex roof geometry can effectively reduce extreme corner suction by 29% and roof uplift by 5.6%.
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来源期刊
Frontiers in Built Environment
Frontiers in Built Environment Social Sciences-Urban Studies
CiteScore
4.80
自引率
6.70%
发文量
266
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