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http://dx.doi.org/10.6110/KJACR.2016.28.1.001

A Study of Wind Pressure Distribution for a Rectangular Building Using CFD  

Shin, Dongshin (Department of Mechanical System Design Engineering,, Hongik University)
Park, Jaehyun (Department of Mechanical System Design Engineering,, Hongik University)
Kang, Bomi (Department of Mechanical System Design Engineering,, Hongik University)
Kim, Eunmi (Department of Mechanical System Design Engineering,, Hongik University)
Lim, Hyeongjun (Department of Mechanical System Design Engineering,, Hongik University)
Lee, Jinyoung (HIMEC Co., Ltd.)
Publication Information
Korean Journal of Air-Conditioning and Refrigeration Engineering / v.28, no.1, 2016 , pp. 1-6 More about this Journal
Abstract
This paper studies the wind pressure distribution over the Commonwealth Advisory Aeronautical Council building model (CAARC model) using CFD. We also considered the interaction between the CAARC model and other buildings. The Reynolds number based on the building height was 380,000. The number of sells for the simulation was about 500,000. The wind pressure was lowest when the wind direction was blowing at an angle 45 degrees of the CAARC model. When the gap between the two buildings in front of the CAARC was over 1/2 the horizontal length of the CAARC model, the wind pressure was higher than the pressure without the two buildings. When the distance between the two front buildings and the CAARC was less than 1.5 times the vertical length of the CAARC model, the wind pressure increased. Accordingly, the relative distance between two buildings or the distance from the CAARC model should be considered when extra wind exists due to other buildings.
Keywords
CFD; Standard tall building; Wind pressure; Building wind; Standard ${\kappa}$-epsilon turbulence model;
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