Litcius/Paper detail

Pedestrian Wind Comfort Assessment Using Computational Fluid Dynamics Simulations With Varying Number of Wind Directions

Trond-Ola Hågbo, Knut Erik Teigen Giljarhus

2022Frontiers in Built Environment30 citationsDOIOpen Access PDF

Abstract

The construction of a building inevitably changes the microclimate in its vicinity. Many city authorities request comprehensive wind studies before granting a building permit, which can be obtained through Computational Fluid Dynamics (CFD) simulations. Investigating the wind conditions for 12 wind directions has previously been considered sufficient in most literature and the industry. However, the effect of changing the number of simulated wind directions is still not well understood. This article investigates the influence of the number of simulated wind directions on pedestrian wind comfort maps. A neighborhood in Niigata city, Japan, was chosen as a case study. Simulations are performed in OpenFOAM using a Reynolds-averaged Navier-Stokes model and the realizable k- ϵ turbulence model. The inlet profiles form a homogeneous atmospheric boundary layer with neutral stratified conditions and a logarithmic velocity profile. The pedestrian wind comfort maps are converging toward a final map as more wind directions are included. The area of the maps classified with the same comfort as using 64 wind directions is 79% using 4 wind directions, 92% using 8 wind directions, 96% using 16 wind directions, and 99% using 32 wind directions. A greater understanding of the influence of the number of simulated wind directions included may enable more efficient pedestrian wind comfort studies that recognize the associated uncertainties.

Topics & Concepts

Computational fluid dynamicsWind speedPedestrianMeteorologyWind directionTurbulenceEnvironmental scienceWind profile power lawCFD in buildingsPlanetary boundary layerWind engineeringWind tunnelMarine engineeringEngineeringAerospace engineeringGeographyCivil engineeringWind and Air Flow StudiesAerodynamics and Fluid Dynamics ResearchUrban Heat Island Mitigation