EXP 1-2: Difference between revisions
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= Abstract = | = Abstract = | ||
Understanding the transport and dispersion of pollutants in street canyons, even under neutral atmospheric conditions, is a major challenge. This study presents a dataset obtained from a wind tunnel experiment with two different 3D city models exposed to two wind directions to illustrate the complexity of pollutant transport (both advective and turbulent) between the street canyon and its surroundings. The two city models were designed based on a typical central European city centre with courtyard buildings and pitched roofs. While the first city model had a uniform height, the second model had an uneven height along each street canyon wall. The models were exposed to neutrally stratified atmospheric boundary layer flow in two directions: perpendicular (i.e. 90°) or oblique (i.e. 45°) to the along-axis of the street canyons. The street canyons were polluted by idealised traffic represented by a ground-level line source. | Understanding the transport and dispersion of pollutants in street canyons, even under neutral atmospheric conditions, is a major challenge. This study presents a dataset obtained from a wind tunnel experiment with two different 3D city models exposed to two wind directions to illustrate the complexity of pollutant transport (both advective and turbulent) between the street canyon and its surroundings. The two city models were designed based on a typical central European city centre with courtyard buildings and pitched roofs. While the first city model had a uniform height, the second model had an uneven height along each street canyon wall. The models were exposed to neutrally stratified atmospheric boundary layer flow in two directions: perpendicular (i.e. 90°) or oblique (i.e. 45°) to the along-axis of the street canyons. The street canyons were polluted by idealised traffic represented by a ground-level line source. The instantaneous two velocity components and pollutant concentration were measured simultanouesly at each of the street canyon openings using laser Doppler anemometry (LDA) and a fast response flame ionisation detector (FFID), respectively. From the time series of the velocities and concentration, the basic velocity and pollutant concentration statistics (mean, standard deviation) as well as the momentum and turbulent pollutant fluxes were computed and are presented in the . The data presented are suitable for validating CFD models focusing on flow and pollutant transport in a 3D urban environment. | ||
Revision as of 11:53, 19 June 2023
Pollutant transport between a street canyon and a 3D urban array as a function of wind direction and roof height non-uniformity
Abstract
Understanding the transport and dispersion of pollutants in street canyons, even under neutral atmospheric conditions, is a major challenge. This study presents a dataset obtained from a wind tunnel experiment with two different 3D city models exposed to two wind directions to illustrate the complexity of pollutant transport (both advective and turbulent) between the street canyon and its surroundings. The two city models were designed based on a typical central European city centre with courtyard buildings and pitched roofs. While the first city model had a uniform height, the second model had an uneven height along each street canyon wall. The models were exposed to neutrally stratified atmospheric boundary layer flow in two directions: perpendicular (i.e. 90°) or oblique (i.e. 45°) to the along-axis of the street canyons. The street canyons were polluted by idealised traffic represented by a ground-level line source. The instantaneous two velocity components and pollutant concentration were measured simultanouesly at each of the street canyon openings using laser Doppler anemometry (LDA) and a fast response flame ionisation detector (FFID), respectively. From the time series of the velocities and concentration, the basic velocity and pollutant concentration statistics (mean, standard deviation) as well as the momentum and turbulent pollutant fluxes were computed and are presented in the . The data presented are suitable for validating CFD models focusing on flow and pollutant transport in a 3D urban environment.
Contributed by: Štěpán Nosek — Institute of Thermomechanics of the CAS, v. v. i.
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