Abstract
One of the key issues of recent research on the dispersion inside complex urban environments is the ability to predict dosage-based parameters from the puff release of an airborne material from a point source in the atmospheric boundary layer inside the built-up area. The present work addresses the question of whether the computational fluid dynamics (CFD)–Reynolds-averaged Navier–Stokes (RANS) methodology can be used to predict ensemble-average dosage-based parameters that are related with the puff dispersion. RANS simulations with the ADREA-HF code were, therefore, performed, where a single puff was released in each case. The present method is validated against the data sets from two wind-tunnel experiments. In each experiment, more than 200 puffs were released from which ensemble-averaged dosage-based parameters were calculated and compared to the model’s predictions. The performance of the model was evaluated using scatter plots and three validation metrics: fractional bias, normalized mean square error, and factor of two. The model presented a better performance for the temporal parameters (i.e., ensemble-average times of puff arrival, peak, leaving, duration, ascent, and descent) than for the ensemble-average dosage and peak concentration. The majority of the obtained values of validation metrics were inside established acceptance limits. Based on the obtained model performance indices, the CFD-RANS methodology as implemented in the code ADREA-HF is able to predict the ensemble-average temporal quantities related to transient emissions of airborne material in urban areas within the range of the model performance acceptance criteria established in the literature. The CFD-RANS methodology as implemented in the code ADREA-HF is also able to predict the ensemble-average dosage, but the dosage results should be treated with some caution; as in one case, the observed ensemble-average dosage was under-estimated slightly more than the acceptance criteria. Ensemble-average peak concentration was systematically underpredicted by the model to a degree higher than the allowable by the acceptance criteria, in 1 of the 2 wind-tunnel experiments. The model performance depended on the positions of the examined sensors in relation to the emission source and the buildings configuration. The work presented in this paper was carried out (partly) within the scope of COST Action ES1006 “Evaluation, improvement, and guidance for the use of local-scale emergency prediction and response tools for airborne hazards in built environments”.
This is a preview of subscription content, log in via an institution to check access.
(pictures courtesy of Professor Bernd Leitl)
Similar content being viewed by others
Notes
Data set contacts are available in http://elizas.eu/index.php/data-set-contacts.html.
References
Bartzis JG (1989) Turbulent diffusion modelling for wind flow and dispersion analysis. Atmos Environ 23:1963–1969
Bartzis JG, Venetsanos A, Varvayani M, Catsaros N, Megaritou A (1991) ADREA-I: a three-dimensional transient transport code for complex terrain and other applications. Nucl Technol 94:135–148
Baumann-Stanzer K, Andronopoulos S, Armand P, Berbekar E, Efthimiou G, Fuka V, Gariazzo C, Gasparac G, Harms F, Hellsten A, Jurcacova K, Petrov A, Rakai A, Stenzel S, Tavares R, Tinarelli G, Trini Castelli S (2015) COST ES1006—model evaluation case studies: approach and results. COST Action ES1006
Berbekar E, Harms F, Leitl B (2015) Dosage-based parameters for characterization of puff dispersion results. J Hazard Mater 283:178–185
Biltoft CA (2001) Customer report for Mock Urban Setting Test. DPG Document No. WDTC-FR-01-121, West Desert Test Center, U.S. Army Dugway Proving Ground, Dugway
Ching WH, Leung MKH, Leung DYC (2009) An efficient approach to transient turbulent dispersion modeling by CFD–statistical analysis of a many-puff system. Fluid Dyn Res 41:17
Cui H, Yao R, Xu X, Xin C, Yang J (2011) A tracer experiment study to evaluate the CALPUFF real time application in a near-field complex terrain setting. Atmos Environ 45:7525–7532
Efthimiou GC, Berbekar E, Harms F, Bartzis JG, Leitl B (2015) Prediction of high concentrations and concentration distribution of a continuous point source release in a semi-idealized urban canopy using CFD-RANS modeling. Atmos Environ 100:48–56
Efthimiou GC, Andronopoulos S, Bartzis JG, Berbekar E, Harms F, Leitl B (2016a) CFD-RANS prediction of individual exposure from continuous release of hazardous airborne materials in complex urban environments. J Turbul. doi:10.1080/14685248.2016.1246736
Efthimiou GC, Andronopoulos S, Tolias I, Venetsanos A (2016b) Prediction of the upper tail of concentration distributions of a continuous point source release in urban environments. Environ Fluid Mech. doi:10.1007/s10652-016-9455-2
Fischer R, Bastigkeit I, Leitl B, Schatzmann M (2010) Generation of spatio-temporally high resolved datasets for the validation of LES-models simulating flow and dispersion phenomena within the lower atmospheric boundary layer. In: Proceedings of fifth international symposium on computational wind engineering (CWE2010), Chapel Hill
Hanna S, Chang J (2012) Acceptance criteria for urban dispersion model evaluation. Meteorol Atmos Phys 116:133–146
Hanna SR, Briggs GA, Hosker RP (1982) Handbook on atmospheric diffusion, national technical information service. U.S. Department of Commerce, Spring-field
Harms F, Leitl B, Schatzmann M, Patnaik G (2011) Validating LES-based flow and dispersion models. J Wind Eng Ind Aerodyn 99:289–295
Hertwig D, Efthimiou GC, Bartzis JG, Leitl B (2012) CFD-RANS model validation of turbulent flow in a semi-idealized urban canopy. J Wind Eng Ind Aerodyn 111:61–72
Kovalets IV, Andronopoulos S, Venetsanos AG, Bartzis JG (2008) Optimization of the numerical algorithms of the ADREA-I mesoscale prognostic meteorological model for real-time applications. Environ Model Softw 23:96–108
Moult A, Spalding DB, Markatos NCG (1979) Solution of flow problems in highly irregular domains by the finite difference method. Trans Inst Chem Eng 57:200–204
Schatzmann M, Olesen H, Franke J (2010) COST 732 Model evaluation case studies: approach and results. ISBN: 3-00-018312-4
Sha WT (1980) An overview on rod-bundle thermal-hydraulic analysis. Nucl Eng Des 62:1–24
Thomson DJ, Jones AR (2011) A new puff modelling technique for short range dispersion applications. Int J Environ Pollut 44:156–163
Venetsanos AG, Papanikolaou E, Bartzis JG (2010) The ADREA-HF CFD code for consequence assessment of hydrogen applications. Int J Hydrogen Energy 35:3908–3918
Wan J, Sui J, Yu H (2014) Research on evacuation in the subway station in China based on the combined social force model. Phys A 394:33–46
Yim SHL, Fung JCH, Lau AKH (2010) Use of high-resolution MM5/CALMET/CALPUFF system: SO2 apportionment to air quality in Hong Kong. Atmos Environ 44:4850–4858
Acknowledgements
The work presented in this paper was carried out (partly) within the scope of COST Action ES1006. The scientific exchange between Action Members and support provided by COST are gratefully acknowledged. The reference data set (“Michelstadt”/“CUTE”) was compiled by members of COST Action ES1006. The provision of reference data is gratefully acknowledged.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: M. T. Prtenjak.
Rights and permissions
About this article
Cite this article
Efthimiou, G.C., Andronopoulos, S. & Bartzis, J.G. Prediction of dosage-based parameters from the puff dispersion of airborne materials in urban environments using the CFD-RANS methodology. Meteorol Atmos Phys 130, 107–124 (2018). https://doi.org/10.1007/s00703-017-0506-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00703-017-0506-0