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2022, vol. 20, br. 1, str. 71-78
Development of methods for assessing the safety of light hydrocarbon storage facilities in emergency situations
(naslov ne postoji na srpskom)
Industrial University of Tyumen, Department of Technosphere Security, Tyumen, Russian Federation

e-adresamo11577.mm@gmail.com
Ključne reči: air stagnation zones; safety; modelling; computational fluid dynamics; light hydrocarbons
Sažetak
(ne postoji na srpskom)
The risk of accidents involving light hydrocarbons is caused by the physicochemical properties of the components, primarily propane and butane. The most catastrophic accidents involving these substances were on November 19, 1984, in the city of San Juan Ixhuatepec (Mexico) and on June 4, 1989, on the Asha - Ulu-Telyak section (USSR), in each of which more than 500 people died. The novelty of the study is determined by the requirement to ensure industrial and fire safety of storage facilities for light hydrocarbons by predicting probable zones of air flow stagnation. The authors calculated the formation of probable air stagnation zones for various space-planning solutions by using a three-dimensional modelling system and the finite volume method. The paper developed a methodology for assessing the safety of storage facilities for light hydrocarbons in emergency situations, which is based on the analysis of probable air stagnation zones by using three-dimensional modelling systems. The practical significance of the study is determined by the additional development of a parameter for assessing the safety state of a storage facility for light hydrocarbons (Ks) and a resulting parameter (Kr) for calculating the optimal location of structures and their structural changes. Integration of stagnation zone sizes into a single formula with the results of other safety calculations is an urgent scientific and applied problem.
Reference
Anderson, J., Romanak, K., Alfi, M., Hovorka, S. (2019) Light hydrocarbon and noble gas migration as an analogue for potential CO2 leakage: Numerical simulations and field data from three hydrocarbon systems. Greenhouse Gases: Science and Technology, vol. 9, no. 2, 226-244
Anderson, J.S., Romanak, K.D., Meckel, T.A. (2018) Assessment of shallow subsea hydrocarbons as a proxy for leakage at offshore geologic CO2 storage sites. International Journal of Greenhouse Gas Control, vol. 74, 19-27
Belmabkhout, Y., Mouttaki, H., Eubank, J.F., Guillerm, V., Eddaoudi, M. (2014) Effect of pendant isophthalic acid moieties on the adsorption properties of light hydrocarbons in HKUST-1-like tbo -MOFs: Application to methane purification and storage. RSC Advances, vol. 4, no. 109, 63855-63859
Cañipa-Morales, N.K., Galán-Vidal, C.A., Guzmán-Vega, M.A., Jarvie, D.M. (2003) Effect of evaporation on C7 light hydrocarbon parameters. Organic Geochemistry, vol. 34, no. 6, 813-826
Chen, B. (2017) An ultrastable and easily regenerated HOF for the selective storage and separation of light hydrocarbons. Science China Chemistry, 60(6): 683-684
Fan, W., Liu, X., Wang, X., Li, Y., Xing, C., Wang, Y., Guo, W., Zhang, L., Sun, D. (2018) A fluorine-functionalized microporous In-MOF with high physicochemical stability for light hydrocarbon storage and separation. Inorganic Chemistry Frontiers, 5(10): 2445-2449
Fan, W., Wang, X., Zhang, X., Liu, X., Wang, Y., Kang, Z., Dai, F., Xu, B., Wang, R., Sun, D. (2019) Fine-Tuning the Pore Environment of the Microporous Cu-MOF for High Propylene Storage and Efficient Separation of Light Hydrocarbons. ACS Central Science, 5(7): 1261-1268
Fu, H.R., Wang, F., Zhang, J. (2015) A stable zinc-4-carboxypyrazole framework with high uptake and selectivity of light hydrocarbons. Dalton Transactions, vol. 44, no. 6, 2893-2896
Fu, H., Zhang, J. (2015) Flexible Porous Zinc-Pyrazole-Adenine Framework for Hysteretic Sorption of Light Hydrocarbons. Crystal Growth & Design, 15(3): 1210-1213
Gong, G., Wu, S., Wu, X. (2018) Influences of light intensity and b-carotene on polycyclic aromatic hydrocarbons and aldehydes in vegetable oil: A case study using palm oil. Journal of Agricultural and Food Chemistry, vol. 66, no. 42, 11124-11132
Huang, P., Chen, C., Wu, M., Jiang, F., Hong, M. (2019) An indium-organic framework for the efficient storage of light hydrocarbons and selective removal of organic dyes. Dalton Transactions, vol. 48, no. 17, 5527-5533
Iaiani, M., Casson, M.V., Reniers, G., Tugnoli, A., Cozzani, V. (2021) Analysis of events involving the intentional release of hazardous substances from industrial facilities. Reliability Engineering and System Safety, vol. 212, article number 107593
Kanazawa, T. (2004) Development of hydrocarbon adsorbents, oxygen storage materials for three-way catalysts and NOx storage-reduction catalyst. Catalysis Today, 96(3): 171-177
Lauritsen, H., Kassold, S., Meneguolo, R., Furre, A. (2018) Assessing potential influence of nearby hydrocarbon production on CO2 storage at Smeaheia. u: CO2 Geological Storage Workshop 2018 (Fifth), p. 1-5
Liu, X., Fan, W., Zhang, M., Li, G., Liu, H., Sun, D., Guo, W. (2018) Enhancing light hydrocarbon storage and separation through introducing Lewis basic nitrogen sites within a carboxylate-decorated copper-organic framework. Materials Chemistry Frontiers, ol. 2, no. 6, 1146-1154
Liu, X., Li, X., Li, J., Li, G., Guo, S., Zhu, H., Zhao, L., Hao, C., Guo, W. (2018) Anionic NbO-type copper organic framework decorated with carboxylate groups for light hydrocarbons separation under ambient conditions. Journal of Materials Science, 53(12): 8866-8877
Omelchuk, M.V. (2017) Scientific substantiation of the methodology for assessing the safety of storage facilities for light hydrocarbons in emergency situations. Ufa: Ufa State Oil Technical University
Permyakov, V.N., Parfenov, V.G., Omelchuk, M.V. (2015) Methodology for assessing the stability of storage facilities for liquefied hydrocarbon gases. Safety and Emergency Issues, 6: 73-79
Vasilyev, A.O., Shemanin, V.G., Chartiy, P.V. (2011) IR detector for hydrocarbons concentration measurement in emissions during petroleum and oil products storage and transportation. u: SPIE, Infrared Sensors, Devices, and Applications; and Single Photon Imaging II, 16 September, Proc., 8155, 81550T
Wang, J., Elsworth, D. (2020) Fracture penetration and proppant transport in gas- and foam-fracturing. Journal of Natural Gas Science and Engineering, 77: 103269-103269
Wang, Y., Wang, X., Wang, X., Zhang, X., Fan, W., Liu, D., Zhang, L., Dai, F., Sun, D. (2019) Effect of Functional Groups on the Adsorption of Light Hydrocarbons in FMJ-type Metal-Organic Frameworks. Crystal Growth & Design, 19(2): 832-838
Zhao, X., Gong, G., Wu, S. (2018) Effect of storage time and temperature on parent and oxygenated polycyclic aromatic hydrocarbons in crude and refined vegetable oils. Food Chemistry, vol. 239, 781-788
 

O članku

jezik rada: engleski
vrsta rada: izvorni naučni članak
DOI: 10.5937/jaes0-30779
primljen: 08.02.2021.
prihvaćen: 31.05.2021.
objavljen u SCIndeksu: 18.03.2022.
metod recenzije: dvostruko anoniman
Creative Commons License 4.0

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