EXP 1-2 Description: Difference between revisions
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=Pollutant transport between a street canyon and a 3D urban array as a function of wind direction and roof height non-uniformity= | =Pollutant transport between a street canyon and a 3D urban array as a function of wind direction and roof height non-uniformity= | ||
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= Description of Study Test Case = | = Description of Study Test Case = | ||
== The general set-up== | == The general set-up== | ||
The following | The following figures show schematically the general set-up of the wind tunnel experiment and the cases investigated. In general, the urban model (either with even height, marked A1, or with uneven height, marked A2) was positioned in the middle of the wind tunnel test section ([[#figure2|Fig 2a]]). To simulate the oblique wind direction, the model was rotated 45 degrees in its centre (corresponding to the centre of the coordinates <i>x,z,y</i>). Since the length (in x-direction) of the urban model was greater than the width (y-direction) of the wind tunnel, the buildings at the upper corners of the urban model were not taken into account after the rotation, and some parts of the buildings were cut off or added according to the walls of the wind tunnel and the length of the development section ([[#figure2|Fig 2c]]). | ||
The first reference street canyon (hereafter called as A1-R, see green rectangle in [[#figure4|Fig 4a]]) was part of the urban model A1, formed by evenly spaced 8 x 4 courtyard-type buildings of constant length (<i>L</i> = 300 mm, i.e. 120 m at full scale) and width (''W'' = 150 mm, i.e. 60 m at full scale) and with pitched roofs of constant height <i>H</i> = 62.5 mm (i.e., 25 m at full scale and corresponds to the height of the roof ridges). The height of the eaves corresponded to <i>z/H</i> = 0.8 (shown in sketch, [[#figure3|Fig 3]]). The second (A2-R) and third (A2-L) street canyons (see green rectangles in [[#figure4|Fig 4b]]) were part of the urban model A2 which had the same layout as the model A1 but had arbitrarily distributed roof heights (0.8<i>H</i>, <i>H</i> or 1.2<i>H</i>) along each building's wall. However, each of the non-uniform street canyons has the same mean height as that of the urban model with the constant roof height (<i>H</i>). | |||
Upstream of the model, a neutrally stratified atmospheric boundary layer was simulated using roughness elements and Irwin spires in the development section of the wind tunnel. Based on the mean height of the building (<i>H</i>) and the free flow velocity <i>U</i><sub>ref</sub> = 6.2 ms<sup>-1</sup> (which was used as the reference velocity), the flow was completely independent of the Reynolds number (i.e. <i>Re<sub>B</sub> = HU<sub>ref</sub>/ν = 24400</i>, where ν is the kinematic viscosity of the air). To simulate the pollution of the street canyons, we used a 1 m long ground-level line source (red line in [[#figure2|Fig 2b]]), which was positioned at the centre line of the investigated street canyons and uniformly emitted a passive gas (ethane). | |||
[[Image:AP1_sketch.cdr| | [[Image:ExpSchema tunel photos.jpg|740px|thumb|center|Figure 2: Schematic representation of the experimental setup in the wind tunnel with reference to the wind tunnel coordinates (x,y,z). a) side view, b) top view, c) snapshots of urban model A1 and A2 in the wind tunnel in relation to the simulated perpendicular (90°) and oblique (45°) wind direction. All dimensions are given in mm. Adapted from [https://doi.org/10.1016/j.jece.2023.109758 Nosek et al. (2023)]]] | ||
[[Image:AP1_sketch.cdr|440px|thumb|center|Figure 3: Sketch of the courtyard buildings forming the street canyon in the urban model A1.]] | |||
==The principal quantities of interest== | ==The principal quantities of interest== | ||
All major flow (mean velocity and turbulence statistics, including momentum fluxes) and pollutant (mean and standard deviation of concentration) concentration | All major flow (mean velocity and turbulence statistics, including momentum fluxes) and pollutant (mean and standard deviation of concentration) concentration quantities, as well as turbulent and mean (advective) pollutant fluxes, were measured at the top (labelled T, [[#figure4|Fig 4c]]) and lateral ([[#figure4|Fig 4d]]) openings of the studied street canyon only for the canyons shown in green in [[#figure4|Fig 4a and b]]. All these quantities are included in the data files, which are provided in the [[EXP 1-2 Measurement Data and Results| Measuring data and Results]]. Due to the uneven roof height, all quantities were measured at two heights in the case of the top openings. The first height was chosen at <i>z/H</i> = 0.6, which corresponds to the lowest street canyon wall (without taking roof pitches into account, see the side cut at A-A in [[#figure4|Fig 4d]]). This height thus enclosed each street canyon of the non-uniform urban model from top. The second at <i>z/H</i> = 1 was chosen as the reference height for both urban models. In the case of the lateral openings, all quantitates were measured at the right (labelled R when viewed from downstream ) and left (labelled L) openings of each street canyon studied up to the height <i>z/H</i> = 0.6. At the top openings, the longitudinal (<i>u</i>) and vertical (<i>w</i>) velocity components were measured simultaneously, while at the lateral openings, the longitudinal (<i>u</i>) and lateral (<i>v</i>) velocity components were measured. Therefore, the vertical and lateral turbulent pollution fluxes were measured for the upper and lateral openings, respectively. The details about the experimetn and the studied cases can be found in [https://doi.org/10.1016/j.envpol.2017.03.073 Nosek et al. (2017)] | ||
[[Image: | [[Image:Schema_2.jpg|740px|thumb|center|Figure 4: Schematic representation of the studied street canyons (green rectangles) in the city models with (a) uniform (with equal height H) and (b) non-uniform height. Measurement grid for the (c) top and the (d) lateral openings for all three investigated street canyons. The red line in (a) and (b) represents the near-ground line source, and the grey contours represent the dimensionless height, z/H, of each of the building segment. (d) is the vertical (xz) cut (lateral view along the x-axis) at the position y/H = -5.12 of the urban model A2. Adapted from [https://doi.org/10.1016/j.buildenv.2018.04.036 Nosek et al. (2018)]]] | ||
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© copyright ERCOFTAC {{CURRENTYEAR}} | © copyright ERCOFTAC {{CURRENTYEAR}} |
Latest revision as of 10:22, 4 August 2023
Pollutant transport between a street canyon and a 3D urban array as a function of wind direction and roof height non-uniformity
Description of Study Test Case
The general set-up
The following figures show schematically the general set-up of the wind tunnel experiment and the cases investigated. In general, the urban model (either with even height, marked A1, or with uneven height, marked A2) was positioned in the middle of the wind tunnel test section (Fig 2a). To simulate the oblique wind direction, the model was rotated 45 degrees in its centre (corresponding to the centre of the coordinates x,z,y). Since the length (in x-direction) of the urban model was greater than the width (y-direction) of the wind tunnel, the buildings at the upper corners of the urban model were not taken into account after the rotation, and some parts of the buildings were cut off or added according to the walls of the wind tunnel and the length of the development section (Fig 2c).
The first reference street canyon (hereafter called as A1-R, see green rectangle in Fig 4a) was part of the urban model A1, formed by evenly spaced 8 x 4 courtyard-type buildings of constant length (L = 300 mm, i.e. 120 m at full scale) and width (W = 150 mm, i.e. 60 m at full scale) and with pitched roofs of constant height H = 62.5 mm (i.e., 25 m at full scale and corresponds to the height of the roof ridges). The height of the eaves corresponded to z/H = 0.8 (shown in sketch, Fig 3). The second (A2-R) and third (A2-L) street canyons (see green rectangles in Fig 4b) were part of the urban model A2 which had the same layout as the model A1 but had arbitrarily distributed roof heights (0.8H, H or 1.2H) along each building's wall. However, each of the non-uniform street canyons has the same mean height as that of the urban model with the constant roof height (H).
Upstream of the model, a neutrally stratified atmospheric boundary layer was simulated using roughness elements and Irwin spires in the development section of the wind tunnel. Based on the mean height of the building (H) and the free flow velocity Uref = 6.2 ms-1 (which was used as the reference velocity), the flow was completely independent of the Reynolds number (i.e. ReB = HUref/ν = 24400, where ν is the kinematic viscosity of the air). To simulate the pollution of the street canyons, we used a 1 m long ground-level line source (red line in Fig 2b), which was positioned at the centre line of the investigated street canyons and uniformly emitted a passive gas (ethane).
The principal quantities of interest
All major flow (mean velocity and turbulence statistics, including momentum fluxes) and pollutant (mean and standard deviation of concentration) concentration quantities, as well as turbulent and mean (advective) pollutant fluxes, were measured at the top (labelled T, Fig 4c) and lateral (Fig 4d) openings of the studied street canyon only for the canyons shown in green in Fig 4a and b. All these quantities are included in the data files, which are provided in the Measuring data and Results. Due to the uneven roof height, all quantities were measured at two heights in the case of the top openings. The first height was chosen at z/H = 0.6, which corresponds to the lowest street canyon wall (without taking roof pitches into account, see the side cut at A-A in Fig 4d). This height thus enclosed each street canyon of the non-uniform urban model from top. The second at z/H = 1 was chosen as the reference height for both urban models. In the case of the lateral openings, all quantitates were measured at the right (labelled R when viewed from downstream ) and left (labelled L) openings of each street canyon studied up to the height z/H = 0.6. At the top openings, the longitudinal (u) and vertical (w) velocity components were measured simultaneously, while at the lateral openings, the longitudinal (u) and lateral (v) velocity components were measured. Therefore, the vertical and lateral turbulent pollution fluxes were measured for the upper and lateral openings, respectively. The details about the experimetn and the studied cases can be found in Nosek et al. (2017)
Contributed by: Štěpán Nosek — Institute of Thermomechanics of the CAS, v. v. i.
© copyright ERCOFTAC 2024