Approaches to substantiating the placement of industrial facilities within the sanitary protection zones of surface watercourses
- Authors: Nikulenkov A.M.1, Yeremin G.B.2, Stepaikina P.V.1, Borisova D.S.2,3, Mozzhukhina N.A.3, Isaev D.S.2
-
Affiliations:
- Sergeev Institute of Environmental Geoscience Russian Academy of Sciences
- North-West Public Health Research Center
- North-West State Medical University named after I.I. Mechnikov
- Issue: Vol 103, No 8 (2024)
- Pages: 814-821
- Section: ENVIRONMENTAL HYGIENE
- Published: 25.09.2024
- URL: https://medjrf.com/0016-9900/article/view/638155
- DOI: https://doi.org/10.47470/0016-9900-2024-103-8-814-821
- EDN: https://elibrary.ru/jmkwob
- ID: 638155
Cite item
Abstract
Introduction. The article considers an approach to be used to delineate the source water protection area for the surface water bodies without putting manufacturing plants within the delineated areas out of action. The approach is based on the assessment of the disposals produced by plants on the water quality at the surface water intake point during the plant’s accident-free operation and both accidents within and beyond the design basis.
Materials and methods. The article used the water protection area laws and regulations, the data observed of the disposal dispersion in the large rivers, and the original articles presented in databases and information systems: RSCI, CyberLeninka, Scopus, Web of Science. The solute transport analytical solutions for the dilution of the linear source in the flow serve as the methodological framework.
Results. The article results have shown the local disposal into the river to form dispersion halo. Due to the specific dispersion processes, an area of a strip-like shape on the opposite shore can be formed where an anthropogenic influence is not present or negligible. This can be considered the background for the safe cooperative operation of the water intake and a manufacturing plant located within the water protection area.
Limitations. The present article outlines the analytical approach for estimating the dilution of wastewater in river waters. The methodologies proposed are subject to several constraints, including the assumption of a constant river channel width and profile, steady discharge of contaminated wastewater, absence of water inflow losses or replenishment, lack of interaction with suspended particulate matter, uniform mixing across all segments of the river, and neglect of wind-induced effects on pollutant dispersion near the water surface. Failure to meet any of these assumptions necessitates recourse to more sophisticated numerical modelling techniques for accurate calculation.
Conclusion. The use of the approach presented in the paper allows justifying the manufacturing plant’s operation within the source water protection area for the surface water bodies.
Compliance with ethical standards. The opinion of the ethics committee is not required.
Contribution:
Nikulenkov A.M. – the concept and design of the study, collection and processing of materials, writing the text;
Yeremin G.B. – the concept and design of the study, approval of the final version of the article, responsibility for the integrity of all parts of the article;
Stepaikina P.V. – the concept and design of the study, collection and processing of materials, editing;
Borisova D.S. – collection and processing of materials, editing;
Mozzhukhina N.A. – writing the text, editing;
Isaev D.S. – editing.
Conflict of interest. The authors declare no conflict of interest.
Acknowledgement. The study had no sponsorship.
Received: May 3, 2024 // Accepted: June 19, 2024 / Published: September 10, 2024
About the authors
Anton M. Nikulenkov
Sergeev Institute of Environmental Geoscience Russian Academy of Sciences
Author for correspondence.
Email: annik@hgepro.ru
ORCID iD: 0000-0001-5498-076X
MD, PhD, leading researcher, head of the Laboratory of Experimental Hydrogeology and Hydrogeomechanics, Sergeev Institute of Geoecology, Russian Academy of Sciences, St.-Petersburg, 199004, Russian Federation
e-mail: annik@hgepro.ru
Russian FederationGennadiy B. Yeremin
North-West Public Health Research Center
Email: yeremin45@yandex.ru
ORCID iD: 0000-0002-1629-5435
MD, PhD, Honoured Doctor of the Russian Federation, leading researcher, head of the Hygiene Department, Sergeev Institute of Environmental Geoscience Russian Academy of Sciences, St.-Petersburg, 199004, Russian Federation
e-mail: yeremin45@yandex.ru
Russian FederationPolina V. Stepaikina
Sergeev Institute of Environmental Geoscience Russian Academy of Sciences
Email: pstepaikina@hgepro.ru
ORCID iD: 0009-0002-0438-2336
Junior researcher, Laboratory of Hydrogeological Forecasts and Modeling, St. Petersburg Branch of the Sergeev Institute of Environmental Geoscience Russian Academy of Sciences, St.-Petersburg, 199004, Russian Federation
e-mail: pstepaikina@hgepro.ru
Russian FederationDarya S. Borisova
North-West Public Health Research Center; North-West State Medical University named after I.I. Mechnikov
Email: vyucheyskaya.ds@gmail.com
ORCID iD: 0000-0003-1778-4465
Junior research fellow, Department of Hygiene, North-West Public Health Research Center, 191036, St.-Petersburg, 191036, Russian Federation, Postgraduate Student, Department of Preventive Medicine and Health Protection, Assistant, Department of General and Military Hygiene, North-West State Medical University named after I.I. Mechnikov, St.-Petersburg, 191015, Russian Federation
e-mail: vyucheyskaya.ds@gmail.com
Russian FederationNatalya A. Mozzhukhina
North-West State Medical University named after I.I. Mechnikov
Email: Natalya.Mozzhukhina@szgmu.ru
ORCID iD: 0000-0002-8051-097X
MD, PhD, Associate Professor, Department of Preventive Medicine and Health Protection, Department of General and Military Hygiene, North-West State Medical University named after I.I. Mechnikov, St.-Petersburg, 191015, Russian Federation
e-mail: Natalya.Mozzhukhina@szgmu.ru
Russian FederationDaniil S. Isaev
North-West Public Health Research Center
Email: d.isaev@s-znc.ru
ORCID iD: 0000-0002-9165-1399
Head of the Dept. of Communal hygiene North-West Public Health Research Center, 191036, St.-Petersburg, 191036, Russian Federation
e-mail: d.isaev@s-znc.ru
Russian FederationReferences
- Report «On the state and use of water resources of the Russian Federation in 2020». Moscow: Rosvodresursy, NIA-Priroda; 2022. (in Russian)
- Kuryndin A.V., Shapovalov A.S., Stroganov A.A., Orlov M.Yu., Timofeev N.B., Korshunkov A.V., et al. Methodological Manual on Regulating Environmental Pollution and the Discharge of Radioactive Substances into the Environment [Metodicheskoe posobie po voprosam regulirovaniya vybrosov i sbrosov radioaktivnykh veshchestv v okruzhayushchuyu sredu]. Moscow; 2023. (in Russian)
- Karaushev A.V., ed. Methodological Basis for Assessing and Regulating Anthropogenic Impact on the Quality of Surface Waters [Metodicheskie osnovy otsenki i reglamentirovaniya antropogennogo vliyaniya na kachestvo poverkhnostnykh vod]. Leningrad: Gidrometeoizdat; 1987. (in Russian)
- IAEA. Generic Models for Use in Assessing the Impact of Discharges of Radioactive Substances to the Environment. Safety Report Series № 19. Vienna; 2001.
- Nosov A.V., Ashanin M.V., Ivanov A.B., Martynova A.M. Radioactive contamination of the Yenisei caused by discharges from the Krasnoyarsk Mining and Chemical Combine. Atomnaya energiya. 1993; 74(2): 144–9. (in Russian)
- Nosov A.V., Krylov A.L., Kiselev V.P., Kazakov S.V. Modeling the Migration of Radionuclides in Surface Waters [Modelirovanie migratsii radionuklidov v poverkhnostnykh vodakh]. Moscow: Nauka; 2010. (in Russian)
- Mellor G.L. Users Guide for a Three-Dimensional, Primitive Equation, Numerical Ocean Model. Princeton: Princeton University; 2004.
- Booth R.S. A systems analysis model for calculating radionuclide transport between receiving water and bottom sediments. In: Miller M.W.M., ed. Environmental Toxicity of Aquatic Radionuclides: Models and Mechanisms. Ann Arbor: Ann Arbor Science; 1976: 133–64.
- Di Torо D.M., О’Соnnor D.J., Thomann R.V. Simplified Model of the Fate Portioning Chemicals in Lakes and Streams. Modelling the Fate of Chemicals in Aquatic Environment. Ann Arbor: Ann Arbor Science; 1982: 165–90.
- Borzilov V.A., Vozzhennikov O.I., Novitskii M.A. Mathematical model of the entry and transfer of chemicals along a large river. In: Behavior of Pesticides and Chemicals in the Environment: Proceedings of the Soviet-American Symposium [Povedenie pestitsidov i khimikatov v okruzhayushchei srede: Trudy sovetsko-amerikanskogo simpoziuma]. Leningrad: Gidrometeoizdat; 1991: 140–59. (in Russian)
- Adcroft A., Hill C., Campin J.M. Overview of the formulation and numerics of the MITgcm. In: Seminar Series on Numerical Methods, Recent Developments in Numerical Methods for Atmosphere and Ocean Modelling. ECMWF; 2004: 139–49.
- Klevannyi K.A., Smirnova E.V. Using the Cardinal software package. Zhurnal universiteta vodnykh kommunikatsii. 2009; (1): 153–62. https://elibrary.ru/mtbmsr (in Russian)
Supplementary files
