Flow mechanisms and flow capacity in idealized long-street city models

Abstract It is an open question whether a street network of a city has a certain flow capacity characterizing the flow that can pass through the street network. It s our hypothesis that at least the simple street network has a certain flow capacity. With the purpose of exploring this we studied numerically and experimentally the flow capacity in some idealized long-street models continuously lined with buildings and exposed to a parallel approaching wind. The height of all the models is the same ( H  = 69 mm). Three groups of models were studied: models with the same uniform street width ( W  =  H ) but different lengths ( L  = 21.7 H , 43.5 H , 72.5 H ); models with the same length ( L  = 43.5 H ) but different uniform width ( W  =  H , 2 H , 4 H ); and models with a change of width at half distance, L /2. In the last of the three cases, the width of the upstream half was always the same ( W 1 =  H ), but there was a wider ( W 2 = 1.25 H , 1.5 H , 2 H ) or narrower ( W 2 = 0.75 H , 0.5 H ) downstream half. We normalized flow rates by a reference flow rate equal to the flow rate through an opening far upstream with the same area as the windward entry. The normalized flow rate through the windward entry was about 1.0 in all cases. For a sufficiently long-street models, a flow balance is established, creating a fully developed region with a constant horizontal flow (flow capacity) and zero vertical mean velocity. The street length does not affect the flow capacity but as expected the width of the street affects the flow capacity.

[1]  Pietro Salizzoni,et al.  Flow in a Street Canyon for any External Wind Direction , 2008 .

[2]  Mats Sandberg,et al.  An Alternative View on the Theory of Cross-Ventilation , 2004 .

[3]  R. Britter,et al.  FLOW AND DISPERSION IN URBAN AREAS , 2003 .

[4]  Mats Sandberg,et al.  Effect of urban morphology on wind condition in idealized city models , 2009 .

[5]  J. Fenger,et al.  Urban air quality , 1999 .

[6]  Mukesh Khare,et al.  Wind tunnel simulation studies on dispersion at urban street canyons and intersections—a review , 2005 .

[7]  Huang Zhen,et al.  The impact of urban street layout on local atmospheric environment , 2006 .

[8]  Fue-Sang Lien,et al.  A comparison of large Eddy simulations with a standard k–ε Reynolds-averaged Navier–Stokes model for the prediction of a fully developed turbulent flow over a matrix of cubes , 2003 .

[9]  Richard Griffiths,et al.  Field experiments of dispersion through regular arrays of cubic structures , 1997 .

[10]  Cheng-Hsin Chang,et al.  The effect of surroundings with different separation distances on surface pressures on low-rise buildings , 2003 .

[11]  Sandrine Anquetin,et al.  Pollutant dispersion and thermal effects in urban street canyons , 1996 .

[12]  T. Oke Street design and urban canopy layer climate , 1988 .

[13]  Rex Britter,et al.  A numerical study of the flow field and exchange processes within a canopy of urban-type roughness , 2005 .

[14]  Alberto Martilli,et al.  CFD simulation of airflow over a regular array of cubes. Part II: analysis of spatial average properties , 2007 .

[15]  Mats Sandberg,et al.  Numerical and experimental studies of wind environment in an urban morphology , 2005 .

[16]  Rainald Löhner,et al.  Comparisons of model simulations with observations of mean flow and turbulence within simple obstacle arrays , 2002 .

[17]  Jong-Jin Baik,et al.  On the escape of pollutants from urban street canyons , 2002 .

[18]  B. Launder,et al.  The numerical computation of turbulent flows , 1990 .