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The Modelling of Turbulence from Traffic in Urban Dispersion Models — Part I: Theoretical Considerations

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Abstract

The modelling of pollutant dispersion at the street scale in an urban environment requires the knowledge of turbulence generated by the traffic motion in streets. In this paper, a theoretical framework to estimate mechanical turbulence induced by traffic in street canyons at low wind speed conditions is established. The standard deviation of the velocity fluctuations is adopted as a measure of traffic-produced turbulence (TPT). Based on the balance between turbulent kinetic energy production and dissipation, three different parameterisations for TPT suitable for different traffic flow conditions are derived and discussed. These formulae rely on the calculations of constants that need to be estimated on the basis of experimental data. One such estimate has been made with the help of a wind tunnel data set corresponding to intermediate traffic densities, which is the most common regime, with interacting vehicle wakes.

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References

  1. Rotach, M.: 1995, Profiles of turbulence statistics in and above an urban street canyon, Atmos. Environ. 29, 1473–1486.

    Google Scholar 

  2. Louka, P.: 1998, Measurements of Airflow in an Urban Environment, PhD Thesis, University of Reading, U.K.

    Google Scholar 

  3. Vachon, G., Rosant, J-M., Mestayer, P. and Sini, J-F.: 1999, Measurements of dynamic and thermal field in a street canyon, URBCAP Nantes 99. In: Proceedings of the 6th International Conference on Harmonisation within Atmospheric Dispersion Modelling, October 11–14, Rouen, France.

  4. Vachon, G., Louka, P., Rosant, J-M., Mestayer, P. and Sini, J-F.: 2001, Measurements of trafficinduced turbulence within a street canyon during the Nantes'99 experiment. In: Proceedings the Third International Conference on Urban Air Quality, 19–23 March 2001, Loutraki, Greece.

  5. Brown, M.J., Lawson, R.E., Descroix, D.S. and Lee, R.L.: 2000, Mean flow and turbulence measurements around a-D array of buildings in a wind tunnel. In: 11th Conference on Appl. of Air Poll. Met.Long Beach, CA, Jan. 2000.

  6. Schatzmann, M., Leitl, B., Liedtke, J.: 2000, Dispersion in urban environments-Comparison of field measurements with wind tunnel results, J. Environ. Monitor. Assess. 65, 249–257.

    Google Scholar 

  7. Kastner-Klein, P.: 1999, Experimentelle Untersuchung der strômungsmechanischen Transportvorgänge in Straßenschluchten, Doctor Thesis, Dissertationsreihe am Institut für Hydromechanik der Universität Karlsruhe, ISSN 1439–4111, Heft 1999/2.

  8. Kastner-Klein, P., Rotach, M., Brown, M., and Lawson, R.:2000, Spatial variability of mean flow and turbulence fields in street canyons. In: Proceedings of the Third Symposium in Urban Environmnent, 14–18 August2000, Davis, CA, pp. 13–14.

  9. Kastner-Klein, P., Rotach, M. and Fedorovich, E.: 2000,Experimental study on mean flow and turbulence characteristics in an urban roughness sublayer. In: 14th Symp. on Boundary Layers and Turbulence, Aspen, CO, August 2000.

  10. Kastner-Klein, P., Fedorovich, E. and Rotach, M.: 2001, A wind tunnel study of organised and turbulent air motions in urban street canyons.J. Wind Eng. Ind. Aerodyn. 89, 849–861.

    Google Scholar 

  11. Kastner-Klein, P., Berkowicz, R. and Plate, E. J.: 2000, Modelling of vehicle induced turbulence in air pollution studies for streets, Int. J. Environ. Pollut. 14, 496–507.

    Google Scholar 

  12. Kastner-Klein, P., Fedorovich, E., Sini, J.-F. and Mestayer, P.G.: 2000, Experimental and numerical verification of similarity concept for diffusion of car exhaust gases in urban street canyons, J. Environ. Monitor. Assess. 65, 353–361.

    Google Scholar 

  13. Kastner-Klein, P., Berkowicz, R. and Fedorovich, E.: 2001, Evaluation of scaling concepts for traffic-produced turbulence based on laboratory and full-scale concentration measurements in street canyons. In: Proceedings of the Third International Conference on Urban Air Quality, 19–23 March 2001, Loutraki, Greece.

  14. Berkowicz, R.: 2000, OSPM-A parameterised street pollution model, J. Environ. Monitor. Assess. 65, 323–331.

    Google Scholar 

  15. Hertel, O. and Berkowicz, R.: 1989, Operational Street Pollution Model (OSPM). Evaluation of model on data from St. Olavs Street in Oslo, DMU Luft A-135, 77 pp.

  16. Sini, J.-F., Anquetin, S. and Mestayer, P.G.: 1996, Pollutant dispersion and thermal effects in urban street canyons, Atmos. Environ. 30, 2659–2677.

    Google Scholar 

  17. Stern, R. and Yamartino, R. J.: 1998, Development and initial application of the micro-calgrid photochemical model for high-resolution studies of urban environments. In: Preprints 23 rd NATO/CCMS ITM on Air Pollution Modelling and its Applications, 28 September-2 October 1998, Varna, Bulgaria.

  18. Ketzel, M., Berkowicz, R., Flassak, T., Lohmeyer, A. and Kastner-Klein, P.:2001, Adaptation of results from CFD-models and wind tunnels for practical traffic pollution modelling. Accepted extended abstract for the 7th International Conference on Harmonisation within Atmospheric Dispersion Modelling for Regulatory Purposes Belgirate, Italy, May 28–31, 2001.

  19. Eskeridge, R. and Hunt, J.: 1979, Highway modelling. Part I: Prediction of velocity and turbulence fields in the wake of vehicles, J. Appl. Meteorol. 18, 387–400.

    Google Scholar 

  20. Plate, E.J.: 1982, Windkanalmodellierung von Ausbreitungsvorgängen in Stadtgebieten. Kolloquiumsbericht Abgasbelastungen durch den Straßenverkehr, Verlag TÑV, Rheinland.

    Google Scholar 

  21. Kastner-Klein, P., Fedorovich, E., Ketzel, M., Berkowicz, R. and Britter, R.E.: 2003, The modelling of turbulence from traffic in urban dispersion models-Part II: Evaluation against laboratory and full-scale concentration measurements in street canyons, Environ. Fluid Mech. 3, 145–172.

    Google Scholar 

  22. Roberson, J.A. and Crowe, C.T.: 1997, Engineering Fluid Mechanics, John Wiley and Sons, 689 pp. f

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Authors and Affiliations

  1. Department of Engineering, University of Cambridge, Trumpington Street, Cambridge, CB2 1PZ, U.K

    S. Di Sabatino & R.E. Britter

  2. Cambridge Environmental Research Consultants Ltd, Cambridge, U.K

    S. Di Sabatino

  3. Dipartimento di Scienza dei Materiali, University of Lecce, Lecce, Italy

    S. Di Sabatino

  4. School of Meteorology, University of Oklahoma, Norman, U.S.A

    P. Kastner-Klein & E. Fedorovich

  5. Institute for Climate Research ETH Swiss Federal Institute of Technology, Zurich, Switzerland

    P. Kastner-Klein

  6. Department of Atmospheric Environment, National Environmental Research Institute, Roskilde, Denmark

    R. Berkowicz

  7. Institute for Hydromechanics, University of Karlsruhe, Karlsruhe, Germany

    E. Fedorovich

Authors
  1. S. Di Sabatino
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  2. P. Kastner-Klein
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  3. R. Berkowicz
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  4. R.E. Britter
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  5. E. Fedorovich
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Correspondence to S. Di Sabatino.

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Di Sabatino, S., Kastner-Klein, P., Berkowicz, R. et al. The Modelling of Turbulence from Traffic in Urban Dispersion Models — Part I: Theoretical Considerations. Environmental Fluid Mechanics 3, 129–143 (2003). https://doi.org/10.1023/A:1022063608237

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