Redirigiendo al acceso original de articulo en 22 segundos...
Inicio  /  Buildings  /  Vol: 11 Par: 3 (2021)  /  Artículo
ARTÍCULO
TITULO

Computational Simulation of Wind Microclimate in Complex Urban Models and Mitigation Using Trees

Azin Hosseinzadeh and Amir Keshmiri    

Resumen

Due to a rapid increase in urbanisation, accurate wind microclimate assessment is of crucial importance. Evaluating wind flows around buildings is part of the planning application process in the design of new developments. In this study, computational fluid dynamics (CFD) simulations are carried out for a case study, representing the East Village in the London Olympic Park. Following a validation test against experimental data for a simpler urban configuration, the key input parameters, including appropriate boundary conditions, mesh setting and type of turbulence model, are selected for the Olympic Park model. All the simulations are conducted using the commercial code STARCCM+ under steady-state conditions with the Reynolds-averaged Navier?Stokes (RANS) method. The turbulence is modelled using different common variants of eddy-viscosity models (EVMs) including standard k-ε" role="presentation">??e e , realizable k-ε" role="presentation">??e e and standard and shear stress transport (SST) k-ω" role="presentation">??? ? . The results demonstrate that standard and realisable k-ε" role="presentation">??e e models correlate very well with the experimental data, while some discrepancies are found with standard and SST k-ω" role="presentation">??? ? . Following the determination of areas of high velocity, appropriate tree planting is proposed to overcome the effect of corner and downwash acceleration. With the optimised arrangement of trees and using specific types of tree (e.g., birch), wind speeds at the pedestrian level are reduced by 3.5, 25 and 66% in three main regions of interest. Moreover, we investigate the effects of tree heights. The obtained results illustrate that the wind velocity reduces when the crowns of the trees are located closer to the buildings and the ground. Our high-resolution CFD simulation and results offer a quantitative tool for wind microclimate assessment and optimised design and arrangement of trees around buildings to improve pedestrian comfort.

 Artículos similares

       
 
Kai Li, Quan Liu, Yuan Tian, Cong Du and Zhixiang Xu    
Asphalt mixtures exhibit complex mechanical behaviors due to their multiphase internal structures. To provide better characterizations of asphalt pavements under various forms of potential distress, a two-dimensional (2D) finite element simulation based ... ver más
Revista: Buildings

 
Dayana Carolina Chalá, Edgar Quiñones-Bolaños and Mehrab Mehrvar    
Land subsidence is a global challenge that enhances the vulnerability of aquifers where climate change and driving forces are occurring simultaneously. To comprehensively analyze this issue, integrated modeling tools are essential. This study advances th... ver más
Revista: Water

 
Sipho G. Thango, Georgios A. Drosopoulos, Siphesihle M. Motsa and Georgios E. Stavroulakis    
A methodology to predict key aspects of the structural response of masonry walls under blast loading using artificial neural networks (ANN) is presented in this paper. The failure patterns of masonry walls due to in and out-of-plane loading are complex d... ver más
Revista: Infrastructures

 
Omar Serghini, Hayat Semlali, Asmaa Maali, Abdelilah Ghammaz and Salvatore Serrano    
Spectrum sensing is an essential function of cognitive radio technology that can enable the reuse of available radio resources by so-called secondary users without creating harmful interference with licensed users. The application of machine learning tec... ver más
Revista: Future Internet

 
Khalid Alnajim and Ahmed A. Abokifa    
In the wake of the terrorist attacks of 11 September 2001, extensive research efforts have been dedicated to the development of computational algorithms for identifying contamination sources in water distribution systems (WDSs). Previous studies have ext... ver más
Revista: Water