Abstract
Reynolds-number dependence of flow fields within a modelled urban area was studied in a wind tunnel. We measured flow around a single model building and around model city blocks at various wind speeds, and studied Reynolds number indices more appropriate than the building Reynolds number. Our results led to the following conclusions. Firstly, the flow around the models in the wind tunnel was roughly divided into three parts according to the intensities of viscous stress and Reynolds stress as follows: (1) the flow in the vicinity of the ground or the surfaces of the model, where viscous stress became dominant under certain conditions; (2) the flow detached from the surfaces of the model, where Reynolds stress was always dominant; and (3) the flow around the separation bubble at the leading edge of the building model, where the influences of both viscous stress near the wall and the Reynolds stress in the separated boundary layer were mixed.Secondly, the critical Reynolds number of the flow in the modelled urban area could be defined by using both the roughness Reynolds number Rez0 (= z0u*/ν) and the dimensionless height z+ (= zu*/ν). Reynolds-number independence could be expected for whole flow fields in the modelled urban areas as long as the critical values of Rez0 and z+ were satisfied.
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References
Castro, I. P. and Robins, A. G.: 1977, 'The Flow around a Surface-Mounted Cube in Uniform and Turbulent Streams', J. Fluid Mech. 79, 307–335.
Hoydysh, W. G., Griffiths, R. A., and Ogawa, Y.: 1974, 'A Scale Model Study of the Dispersion of Pollution in Street Canyons', for presentation at the 67th Annual Meeting of the Air Pollution Control Associatio, 1–13, Denver, CO, June 9–13, 1974, Air Pollution Control Association.
Meng, Y. and Hibi, K.: 1998, 'Turbulent Measurements of the Flow Fields around a High-Rise Building', J. Wind Eng. Japan 76, 55–64.
Mochida, A., Murakami, S., and Kato, S.: 1994, 'The Similarity Requirements for Wind Tunnel Model Studies of Gas Diffusion', J. Wind Eng. Japan 59, 23–28.
Monin, A. S. and Yaglom, A. M.: 1971, Statistical Fluid Mechanics, Vol. 1, The MIT Press, Cambridge, MA, 769 pp.
Ogawa, Y., Diosey, P. G., Uehara, K., and Ueda, H.: 1981, 'A Wind Tunnel for Studying the Effects of Thermal Stratification in the Atmosphere', Atmos. Environ. 15, 807–821.
Ohba, M.: 1989, 'Experimental Studies for Effects of Separated Flow on Gaseous Diffusion around Two Model Buildings', J. Archit. Plann. Environ. Eng. AIJ 406, 21–30.
Schlichting, H.: 1968. Boundary-Layer Theory, 6th edn., McGraw-Hill, New York, 584 pp.
Snyder, W. H.: 1972, 'Similarity Criteria for the Application of Fluid Models to the Study of Air Pollution Meteorology', Boundary-Layer Meteorol. 3, 113–134.
Snyder, W. H.: 1994, 'Some Observations of the Influence of Stratification on Diffusion in Building Wakes', in I. P. Castro and N. J. Rockliff (eds.), Stably Stratified Flows: Flow and Dispersion over Topography, Clarendon Press, Oxford, U.K., pp. 301–324.
Uehara, K., Murakami, S., Oikawa, S., and Wakamatsu, S.: 2000, 'Wind Tunnel Experiments on How Thermal Stratification Affects Flow in and above Urban Street Canyons', Atmos. Environ. 34, 1553–1562.
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Uehara, K., Wakamatsu, S. & Ooka, R. Studies on critical Reynolds number indices for wind-tunnel experiments on flow within urban areas. Boundary-Layer Meteorology 107, 353–370 (2003). https://doi.org/10.1023/A:1022162807729
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DOI: https://doi.org/10.1023/A:1022162807729