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1.
Kovar-Panskus, A., Louka, P., Sini, J.F., Savory, E., Czech, M., Abdelqari, A., Mestayer, P.G. & Toy, N., Influence of geometry on the mean flow within urban street canyons–a comparison of wind tunnel experiments and numerical simulations. Water, Air and Soil Pollution: Focus, 2(5), pp. 365–380, 2002. [Crossref]
2.
Meroney, R.N., Pavageau, M., Rafailidis, S. & Schatzmann, M., Study of line source characteristics for 2-D physical modelling of pollutant dispersion in street canyons. Journal of Wind Engineering and Industrial Aerodynamics, 62(1), pp. 37–56, 1996. [Crossref]
3.
Landrigan, P.J., Fuller, R., Acosta, N.J., Adeyi, O., Arnold, R., Baldé, A.B., Bertollini, R., Bose-O’Reilly, S., Boufford, J.I., Breysse, P.N. & Chiles. T., The Lancet Commis- sion on pollution and health. The Lancet, 391(10119), pp. 462–512, 2018. https://doi. org/10.1016/s0140-6736(17)32345-0
4.
McNabola, A., Broderick, B.M. & Gill. L.W., A numerical investigation of the impact of low boundary walls on pedestrian exposure to air pollutants in urban street canyons. Science of the Total Environment, 407(2), pp. 760–769, 2009. https://doi.org/10.1016/ j.scitotenv.2008.09.036
5.
Gallagher, J., Gill, L.W. & McNabola, A., Optimizing the use of on-street car park- ing system as a passive control of air pollution exposure in street canyons by large eddy simulation. Atmospheric Environment, 45(9), pp. 1684–1694, 2011. https://doi. org/10.1016/j.atmosenv.2010.12.059
6.
Gromke, C., Buccolieri, R., Di Sabatino, S. & Ruck, B., Dispersion study in a street canyon with tree planting by means of wind tunnel and numerical investigations–evalu- ation of CFD data with experimental data. Atmospheric Environment, 42(37), pp. 8640– 8650, 2008. [Crossref]
7.
Kastner-Klein, P. & Plate, E.J., Wind-tunnel study of concentration fields in street canyons. Atmospheric Environment, 33(24–25), pp. 3973–3979, 1999. https://doi. org/10.1016/s1352-2310(99)00139-9
8.
Mirzai, M.H., Harvey, J.K. & Jones, C.D., Wind tunnel investigation of dispersion of pollutants due to wind flow around a small building. Atmospheric Environment, 28(11), pp. 1819–1826, 1994. [Crossref]
9.
Allegrini, J., Dorer, V. & Carmeliet, J., Buoyant flows in street canyons: validation of CFD simulations with wind tunnel measurements. Building and Environment, 72, pp. 63–74, 2014. [Crossref]
10.
Sagrado, A.P., van Beeck, J., Rambaud, P. & Olivari, D., Numerical and experimental modelling of pollutant dispersion in a street canyon. Journal of Wind Engineering and Industrial Aerodynamics, 90(4–5), pp. 321–339, 2002. 6105(01)00215-x [Crossref]
11.
Chang, C.H. & Meroney, R.N., Concentration and flow distributions in urban street canyons: wind tunnel and computational data. Journal of Wind Engineering and In- dustrial Aerodynamics, 91(9), pp. 1141–1154, 2003. 6105(03)00056-4 [Crossref]
12.
Meroney, R.N., Leitl, B.M., Rafailidis, S. & Schatzmann, M., Wind-tunnel and nu- merical modeling of flow and dispersion about several building shapes. Journal of Wind Engineering and Industrial Aerodynamics, 81(1–3), pp. 333–345, 1999. https://doi. org/10.1016/s0167-6105(99)00028-8
13.
Llaguno-Munitxa, M., Bou-Zeid, E. & Hultmark, M., The influence of building geom- etry on street canyon air flow: validation of large eddy simulations against wind tun- nel experiments. Journal of Wind Engineering and Industrial Aerodynamics, 165, pp. 115–130, 2017. [Crossref]
14.
Ding, S., Huang, Y., Cui, P., Wu, J., Li, M. & Liu, D., Impact of viaduct on flow rever- sion and pollutant dispersion in 2D urban street canyon with different roof shapes- Numerical simulation and wind tunnel experiment. Science of the Total Environment, 671, pp. 976–991, 2019. [Crossref]
15.
Gromke, C. & Ruck, B., Influence of trees on the dispersion of pollutants in an ur- ban street canyon—experimental investigation of the flow and concentration field. Atmospheric Environment, 41(16), pp. 3287–3302, 2007. mosenv.2006.12.043 [Crossref]
16.
Gromke, C., A vegetation modeling concept for building and environmental aero- dynamics wind tunnel tests and its application in pollutant dispersion studies. Envi- ronmental Pollution, 159(8–9), pp. 2094–2099, 2011. vpol.2010.11.012 [Crossref]
17.
Cui, P.Y., Li, Z. & Tao, W.Q., Investigation of Re-independence of turbulent flow and pollutant dispersion in urban street canyon using numerical wind tunnel (NWT) mod- els. International Journal of Heat and Mass Transfer, 79, pp. 176–188, 2014. https:// doi.org/10.1016/j.ijheatmasstransfer.2014.07.096
18.
Heist, D.K., Perry, S.G. & Brixey, L.A., A wind tunnel study of the effect of roadway configurations on the dispersion of traffic-related pollution. Atmospheric Environment, 43(32), pp. 5101–5111, 2009. [Crossref]
19.
Kovar-Panskus, A, Louka, P., Mestayer, P.G., Savory, E., Sini, J.F. & Toy, N., Influ- ence of geometry on the flow and turbulence characteristics within urban street can- yons–Intercomparison of wind tunnel experiments and numerical simulations. In Proceedings of the 3rd International Conference on Urban Air Quality (pp. 19–23), 2001.
20.
Chan, T.L., Dong, G., Leung, C.W., Cheung, C.S. & Hung, W.T., Validation of a two- dimensional pollutant dispersion model in an isolated street canyon. Atmospheric en- vironment, 36(5), pp. 861–872, 2002. [Crossref]
21.
Takano, Y. & Moonen, P., On the influence of roof shape on flow and dispersion in an urban street canyon. Journal of Wind Engineering and Industrial Aerodynamics, 123, pp. 107–120, 2013. [Crossref]
22.
Franke, J., Best practice guideline for the CFD simulation of flows in the urban environ- ment. Meteorological Inst., 2007.
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Open Access
Research article

Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements

Madhavan Vasudevan1,
Bidroha Basu1,2,
Francesco Pilla2,
Aonghus Mcnabola1,3
1
Department of Civil, Structural & Environmental Engineering, Trinity College, Dublin, Ireland
2
School of Architecture Planning and Environmental Policy, University College Dublin, Ireland
3
Global Centre for Clean Air Research, Department of Civil and Environmental Engineering, Faculty of Engineering and Physical Sciences (FEPS), University of Surrey, United Kingdom
International Journal of Computational Methods and Experimental Measurements
|
Volume 10, Issue 2, 2022
|
Pages 104-116
Received: N/A,
Revised: N/A,
Accepted: N/A,
Available online: N/A
View Full Article|Download PDF

Abstract:

Precise prediction of air quality in a street canyon under diverse conditions could be established through the comprehensive validation of velocity of wind profiles and the concentration distribu- tion of pollutants. In this study, a two-step approach was developed using Computational Fluid Dynamics simulations. The first step involved the validation of wind velocity profiles obtained using wind tunnel experimental measurements of an isolated street canyon discussed in ref. [1], while the second step focused on the validation of dispersion of pollutants from wind tunnel mea- surements discussed in ref. [2] conducted on isolated and urban street canyons. The wind velocity profiles obtained at five distinct vertical planes between the leeward and windward walls in the wind tunnel study [1] were validated by simulating the 2D cross-section of the entire wind tunnel domain with high accuracies; R2 values of 0.931–0.986 were obtained across the canyon depth. The concentration distribution of the pollutant in the wind tunnel study [2] were validated for a range of velocities (0.5, 1, 2 and 4 m/s) using both 2D and 3D models. A verification of the Reyn- olds independent nature of the flow was performed by comparing the wind tunnel and street scale models and suitability of employing K-e turbulence model with Enhanced Wall Treatment and K-ε Low Reynolds Number Model for the wind tunnel scale, and Standard Wall Functions for the street scale were observed. A 2D simulation of urban street canyon flow representing the whole wind tunnel cross-section in the flow direction was also studied to observe repetitive flow nature and thereby a potential to employ fully developed flow conditions for the same. The urban street canyon flow is established through the means of fully developed periodic flow profiles, which inherently restricts the additional mass sources in the flow domain. The emission scenario in the fully developed flow was captured by means of flow profile mapping at the upwind edge of the leeward building. To estimate the minimum number of downwind canyons required to keep up the fully developed flow profile at the target street canyon, a parameterization of the same was per- formed. Finally, the validation of the concentration profiles was obtained with parameterization of the Schmidt number, and an optimal Schmidt number was obtained in the case of using Realizable K-e turbulence model. The developed and validated methodology provides a robust and efficient means of modelling air pollution dispersion in the isolated and urban street canyons for future research investigations.

Keywords: 2D and 3D simulations, CFD, Fully developed flows, Isolated street canyon, Urban street canyon, Validation

1. Introduction

2. Open Street Configuration

3. Urban Stret Configuration

4. Results

5. Conclusions

Acknowledgments

The authors would like to acknowledge that this study was part funded by the Irish Environ- mental Protection Agency’s Research Programme 2014–2020 through Project Grant Number 2019-PhD-AF-6. The EPA Research Programme is a Government of Ireland initiative funded by the Department of Communications, Climate Action and Environment.

References
1.
Kovar-Panskus, A., Louka, P., Sini, J.F., Savory, E., Czech, M., Abdelqari, A., Mestayer, P.G. & Toy, N., Influence of geometry on the mean flow within urban street canyons–a comparison of wind tunnel experiments and numerical simulations. Water, Air and Soil Pollution: Focus, 2(5), pp. 365–380, 2002. [Crossref]
2.
Meroney, R.N., Pavageau, M., Rafailidis, S. & Schatzmann, M., Study of line source characteristics for 2-D physical modelling of pollutant dispersion in street canyons. Journal of Wind Engineering and Industrial Aerodynamics, 62(1), pp. 37–56, 1996. [Crossref]
3.
Landrigan, P.J., Fuller, R., Acosta, N.J., Adeyi, O., Arnold, R., Baldé, A.B., Bertollini, R., Bose-O’Reilly, S., Boufford, J.I., Breysse, P.N. & Chiles. T., The Lancet Commis- sion on pollution and health. The Lancet, 391(10119), pp. 462–512, 2018. https://doi. org/10.1016/s0140-6736(17)32345-0
4.
McNabola, A., Broderick, B.M. & Gill. L.W., A numerical investigation of the impact of low boundary walls on pedestrian exposure to air pollutants in urban street canyons. Science of the Total Environment, 407(2), pp. 760–769, 2009. https://doi.org/10.1016/ j.scitotenv.2008.09.036
5.
Gallagher, J., Gill, L.W. & McNabola, A., Optimizing the use of on-street car park- ing system as a passive control of air pollution exposure in street canyons by large eddy simulation. Atmospheric Environment, 45(9), pp. 1684–1694, 2011. https://doi. org/10.1016/j.atmosenv.2010.12.059
6.
Gromke, C., Buccolieri, R., Di Sabatino, S. & Ruck, B., Dispersion study in a street canyon with tree planting by means of wind tunnel and numerical investigations–evalu- ation of CFD data with experimental data. Atmospheric Environment, 42(37), pp. 8640– 8650, 2008. [Crossref]
7.
Kastner-Klein, P. & Plate, E.J., Wind-tunnel study of concentration fields in street canyons. Atmospheric Environment, 33(24–25), pp. 3973–3979, 1999. https://doi. org/10.1016/s1352-2310(99)00139-9
8.
Mirzai, M.H., Harvey, J.K. & Jones, C.D., Wind tunnel investigation of dispersion of pollutants due to wind flow around a small building. Atmospheric Environment, 28(11), pp. 1819–1826, 1994. [Crossref]
9.
Allegrini, J., Dorer, V. & Carmeliet, J., Buoyant flows in street canyons: validation of CFD simulations with wind tunnel measurements. Building and Environment, 72, pp. 63–74, 2014. [Crossref]
10.
Sagrado, A.P., van Beeck, J., Rambaud, P. & Olivari, D., Numerical and experimental modelling of pollutant dispersion in a street canyon. Journal of Wind Engineering and Industrial Aerodynamics, 90(4–5), pp. 321–339, 2002. 6105(01)00215-x [Crossref]
11.
Chang, C.H. & Meroney, R.N., Concentration and flow distributions in urban street canyons: wind tunnel and computational data. Journal of Wind Engineering and In- dustrial Aerodynamics, 91(9), pp. 1141–1154, 2003. 6105(03)00056-4 [Crossref]
12.
Meroney, R.N., Leitl, B.M., Rafailidis, S. & Schatzmann, M., Wind-tunnel and nu- merical modeling of flow and dispersion about several building shapes. Journal of Wind Engineering and Industrial Aerodynamics, 81(1–3), pp. 333–345, 1999. https://doi. org/10.1016/s0167-6105(99)00028-8
13.
Llaguno-Munitxa, M., Bou-Zeid, E. & Hultmark, M., The influence of building geom- etry on street canyon air flow: validation of large eddy simulations against wind tun- nel experiments. Journal of Wind Engineering and Industrial Aerodynamics, 165, pp. 115–130, 2017. [Crossref]
14.
Ding, S., Huang, Y., Cui, P., Wu, J., Li, M. & Liu, D., Impact of viaduct on flow rever- sion and pollutant dispersion in 2D urban street canyon with different roof shapes- Numerical simulation and wind tunnel experiment. Science of the Total Environment, 671, pp. 976–991, 2019. [Crossref]
15.
Gromke, C. & Ruck, B., Influence of trees on the dispersion of pollutants in an ur- ban street canyon—experimental investigation of the flow and concentration field. Atmospheric Environment, 41(16), pp. 3287–3302, 2007. mosenv.2006.12.043 [Crossref]
16.
Gromke, C., A vegetation modeling concept for building and environmental aero- dynamics wind tunnel tests and its application in pollutant dispersion studies. Envi- ronmental Pollution, 159(8–9), pp. 2094–2099, 2011. vpol.2010.11.012 [Crossref]
17.
Cui, P.Y., Li, Z. & Tao, W.Q., Investigation of Re-independence of turbulent flow and pollutant dispersion in urban street canyon using numerical wind tunnel (NWT) mod- els. International Journal of Heat and Mass Transfer, 79, pp. 176–188, 2014. https:// doi.org/10.1016/j.ijheatmasstransfer.2014.07.096
18.
Heist, D.K., Perry, S.G. & Brixey, L.A., A wind tunnel study of the effect of roadway configurations on the dispersion of traffic-related pollution. Atmospheric Environment, 43(32), pp. 5101–5111, 2009. [Crossref]
19.
Kovar-Panskus, A, Louka, P., Mestayer, P.G., Savory, E., Sini, J.F. & Toy, N., Influ- ence of geometry on the flow and turbulence characteristics within urban street can- yons–Intercomparison of wind tunnel experiments and numerical simulations. In Proceedings of the 3rd International Conference on Urban Air Quality (pp. 19–23), 2001.
20.
Chan, T.L., Dong, G., Leung, C.W., Cheung, C.S. & Hung, W.T., Validation of a two- dimensional pollutant dispersion model in an isolated street canyon. Atmospheric en- vironment, 36(5), pp. 861–872, 2002. [Crossref]
21.
Takano, Y. & Moonen, P., On the influence of roof shape on flow and dispersion in an urban street canyon. Journal of Wind Engineering and Industrial Aerodynamics, 123, pp. 107–120, 2013. [Crossref]
22.
Franke, J., Best practice guideline for the CFD simulation of flows in the urban environ- ment. Meteorological Inst., 2007.
Cite this:
APA Style
IEEE Style
BibTex Style
MLA Style
Chicago Style
GB-T-7714-2015
Vasudevan, M., Basu, B., Pilla, F., & Mcnabola, A. (2022). Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements. Int. J. Comput. Methods Exp. Meas., 10(2), 104-116. https://doi.org/10.2495/CMEM-V10-N2-104-116
M. Vasudevan, B. Basu, F. Pilla, and A. Mcnabola, "Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements," Int. J. Comput. Methods Exp. Meas., vol. 10, no. 2, pp. 104-116, 2022. https://doi.org/10.2495/CMEM-V10-N2-104-116
@research-article{Vasudevan2022DevelopmentAV,
title={Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements},
author={Madhavan Vasudevan and Bidroha Basu and Francesco Pilla and Aonghus Mcnabola},
journal={International Journal of Computational Methods and Experimental Measurements},
year={2022},
page={104-116},
doi={https://doi.org/10.2495/CMEM-V10-N2-104-116}
}
Madhavan Vasudevan, et al. "Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements." International Journal of Computational Methods and Experimental Measurements, v 10, pp 104-116. doi: https://doi.org/10.2495/CMEM-V10-N2-104-116
Madhavan Vasudevan, Bidroha Basu, Francesco Pilla and Aonghus Mcnabola. "Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements." International Journal of Computational Methods and Experimental Measurements, 10, (2022): 104-116. doi: https://doi.org/10.2495/CMEM-V10-N2-104-116
VASUDEVAN M, BASU B, PILLA F, et al. Development And Validation of a Computational Fluid Dynamics Modelling Methodology for Isolated and Urban Street Canyon Configurations Using Wind Tunnel Measurements[J]. International Journal of Computational Methods and Experimental Measurements, 2022, 10(2): 104-116. https://doi.org/10.2495/CMEM-V10-N2-104-116