Installation Project for Water Purification from Suspended Particles

E.N.  Neverov; A.K.  Gorelkina; E.S.  Mikhalova; P.S.  Korotkih

doi:10.6180/jase.202508_28(8).0018

Installation Project for Water Purification from Suspended Particles

Environmental Engineering Water Resources Engineering

E.N. NeverovThis email address is being protected from spambots. You need JavaScript enabled to view it., A.K. Gorelkina, E.S. Mikhalova, and P.S. Korotkih

Kemerovo State University, 6 Krasnaya str., Kemerovo, 650000, Russia

Received: August 5, 2024
Accepted: September 29, 2024
Publication Date: November 24, 2024

Copyright The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are cited.

Download Citation: ||https://doi.org/10.6180/jase.202508_28(8).0018

Currently, the issue of recycling coal waste becomes quite relevant all over the world, which is associated with tightening environmental standards and increasing production rates in the coal industry. So, to reduce the environmental load of effective coal waste management, innovative developments and implementation are required, aimed at processing, purification and disposal. The aim of this work is to evaluate methods for treating water containing suspended coal dust and to develop a treatment plant design along with approaches for pilot testing. A design of the plant for purifying water with suspended coal dust particles, a diagram of the interaction of elements, feasible technological solutions and options for the operation of the plant are proposed. The implementation of the proposed installation in the ports that ship coal allows us to evaluate not only water purification processes, but also measures aimed at optimizing expended resources and reducing the negative impact on the environment. The research results and technical characteristics of the proposed plant are discussed in the context of its application and benefits to industrial enterprises in the field of coal transportation. The water installation project can serve as the basis for implementing environmentally sustainable solutions in the field of water treatment and increasing the economic efficiency of transporting coal by water in the Caspian area. The proposed water purification plant incurs significant operational costs. Fire hazards in closed systems and coal dust pollution are still issues, even with the plant’s adaptable design.

Keywords: coal waste; mine water; ecology; water treatment facilities; coal; filtration

[1] E. N. Neverov, A. K. Gorelkina, I. V. Tymoshchuk, M. L. Fuks, and L. A. Ivanova, (2023) “High-efficiency hydrocyclone" (RU219222U1):
[2] C.S.S.D.oftheRussian Federation. Resolution of July 21, 2011 No. 102 "On approval of SanPiN 2.2.2948-11 ’Hygienic requirements for organizations engaged in the extraction and processing of coal (oil shale) and organiza tion of work’". 2011.
[3] E. N. Neverov, I. V. Tymoshchuk, A. K. Gorelkina, M. L. Fuks, E. I. Stabrovskaya, and N. N. Turova, (2023) “Sludge tank with replaceable container for hydro cyclone" (RU219524U1):
[4] A.K.Gorelkina, E. S. Mikhailova, I. V. Tymoshchuk, L. A. Ivanova, and E. N. Neverov, (2023) “Wastewater treatment of coal mining enterprises" Coal S12(1175): 63–66.
[5] M.ofConstruction of the Russian Federation. Order of December 27, 2021 No. 1016/pr "On approval of SP 31.13330.2021 "SNiP 2.04.02-84* Water supply. Outdoor networks and structures". 2021.
[6] A.Haslinah, T. Thamrin, T. N. Bandrang, T. Taryana, T. B. Karyasa, B. Purwoko, and A. Andiyan, (2024) “Green technology’s function in the production of renew able energy and mineral extraction" Caspian Journal of Environmental Sciences 22(1): 93–102.
[7] O. A. Gurova and M. P. Sartakov, (2023) “Thermo gravimetric analysis of brown coals and also humic acids as well as their extracted bitumens in the Circumpolar Urals" Caspian Journal of Environmental Sciences 21(5): 1309–1313.
[8] A.K.Gorelkina, T. A. Krasnova, I. V. Tymoshchuk, N. Gora, and N. Golubeva, (2019) “Study of the dynamics of the adsorption of trichloroethylene (TCE) on active car bons" Ecology and Industry of Russia 23(9): 30–35. DOI: 10.18412/1816-0395-2019-9-30-35.
[9] E. N. Neverov, A. K. Gorelkina, and R. Y. Shaplok, (2023) “Analysis of modern methods and technologies of industrial water treatment" Polzunovskiy vestnik 3: 215–225. DOI: 10.25712/ASTU.2072-8921.2023.03.30.
[10] A. Y. Prosekov, I. V. Tymoshchuk, and A. K. Gorelk ina, (2021) “On the issue of the use of waste from water de salting ion exchange units of power plants" Theoretical andAppliedEcology4:127–132. DOI:10.25750/1995-4301-2021-4-127-132.
[11] E.S. Mikhailova, I. V. Tymoshchuk, and A. K. Gorelk ina, (2023) “Methodology for constructing patent land scapes on the example of wastewater treatment of coal min ing enterprises" Coal 10(1172): 28–35. DOI: 10.18796/0041-5790-2023-10-28-35.
[12] A. Y. Prosekov, I. V. Tymoshchuk, A. K. Gorelkina, E. S. Mikhailova, N. S. Golubeva, and L. A. Ivanova, (2023) “Comparative assessment of the content of pollu tants in quarry wastewater of Kuzbass coal enterprises" Coal 4(1166): 69–73. DOI: 10.18796/0041-5790-2023 4-69-73.
[13] A. K. Gorelkina, E. S. Mikhailova, I. V. Tymoshchuk, L. A. Ivanova, and T. A. Utrobina, (2023) “Technogenic load on water resources of coal-mining regions" Occupa tional safety in industry 8: 26–32. DOI: 10.24000/ 0409-2961-2023-8-26-32.
[14] A. K. Gorelkina, I. V. Tymoshchuk, N. S. Golubeva, O. V. Belyaeva, and E. S. Mikhailova, (2023) “Reduc tion of impact of mining on water ecosystems" Mining Information and Analytical Bulletin (Scientific and Technical Journal) 7: 64–75. DOI: 10.25018/0236_ 1493_2023_7_0_64.
[15] O.V.Belyaeva, N. V. Gora, A. K. Gorelkina, N. S. Gol ubeva, and L. A. Ivanova, (2023) “Analysis of the leach ing process of overburden rocks as an additional source of some ions entering quarry wastewater" Ecology of industrial production 3(123): 33–36.
[16] A.M.Koganovsky,L.A.Kulsky, andE.V. Sotnikova. Industrial wastewater treatment. Moscow: Technika, 1974, 257.
[17] F. A. Afanasyeva, A. P. Ivanov, and A. E. Lovtsov, (2003) “Purification of domestic wastewater in compact installations" Water Supply and Sanitary Engineer ing 11: 34–39.
[18] G. of the Russian Federation. Resolution of July 29, 2013 No. 644 "On approval of the Rules of cold water sup ply and sanitation and on amendments to certain acts of the Government of the Russian Federation" (with amend ments and additions). 2013.
[19] I. S. Buzin. Modern methods of wastewater treatment. Date of reference: March 26, 2023. 2022.
[20] V. P. Myazin and O. V. Litvintseva. Circulating water supply of processing plants. Methods of purification and conditioning of wastewater and recycled water. Chita: State Educational Institution of Higher Education "Chita State University" (CHITSU), 2011, 153.
[21] L. A. Ivanova, O. V. Salishcheva, I. V. Timo shchuk, N. S. Golubeva, and A. K. Gorelkina, (2023) “Major wastewater pollutants in coal mining" Coke and Chemistry 66(4): 227–231. DOI: 10.3103/S1068364X23700722.
[22] E. Neverov, A. Gorelkina, I. Korotkiy, and R. Skhap lok, (2023) “Influence of the properties and concentration of pollutants in wastewater on the choice of methods and technologies of industrial water treatment: A systematic review" Advancements in Life Sciences 10(3): 341–349.
[23] A. Prosekov, I. Timoshchuk, A. Gorelkina, N. Gol ubeva, L. Ivanova, and S. Onopenko. “Environmen tal monitoring in the area of the Krapivinsky hydro electric complex during the assessment of the current state and during the construction period of HPP”. In: AIP Conference Proceedings. 2636. 2022, 030003. DOI: 10.1063/5.0104303.
[24] A. K. Gorelkina, T. A. Krasnova, I. V. Timoshchuk, N. V. Gora, and N. S. Golubeva. “Dynamics of trichloroethylene adsorption on activated carbons”. In: IOP Conference Series: Earth and Environmental Sci ence. 315. 2019, 052026. DOI: 10.1088/1755-1315/315/5/052026.
[25] T. Krasnova, Y. L. Skolubovich, D. Volkov, I. Tim oshchuk, and A. Gorelkina. “Study of disinfectant type effect on the organohalogen compounds forma tion in water treatment”. In: IOP Conference Series: Materials Science and Engineering. 953. 2020, 012018. DOI: 10.1088/1757-899X/953/1/012018.
[26] D. Dutta, S. Arya, and S. Kumar, (2021) “Industrial wastewater treatment: Current trends, bottlenecks, and best practices" Chemosphere 285: 131245. DOI: 10.1016/j.chemosphere.2021.131245.
[27] M.B. Ceretta, D. Nercessian, and E. A. Wolski, (2021) “Current trends on role of biological treatment in integrated treatment technologies of textile wastewater" Frontiers in Microbiology 12: DOI: 10.3389/fmicb.2021.651025.
[28] P. Sanghamitra, D. Mazumder, and S. Mukherjee, (2021) “Treatment of wastewater containing oil and grease by biological method- a review" Journal of Environmen tal Science and Health Part A 56(4): 394–412. DOI: 10.1080/10934529.2021.1884468.
[29] M. Simoniˇc, (2021) “Reverse Osmosis Treatment of Wastewater for Reuse as Process Water—A Case Study" Membranes 11(12): 976. DOI: 10.3390/membranes11120976.
[30] H.Valdés, A. Saavedra, M. Flores, I. Vera-Puerto, H. Aviña, and M. Belmonte, (2021) “Reverse osmosis con centrate: physicochemical characteristics, environmental impact, and technologies" Membranes 11(10): 753. DOI: 10.3390/membranes11100753.
[31] A.Anderson, A. Anbarasu, R. R. Pasupuleti, S. Mani gandan, T. Praveenkumar, and J. A. Kumar, (2022) “Treatment of heavy metals containing wastewater using biodegradable adsorbents: A review of mechanism and fu ture trends" Chemosphere 295: 133724. DOI: 10.1016/j.chemosphere.2022.133724.
[32] Z.Zhang,Y.Wu,L.Luo,G.Li,Y.Li,andH.Hu,(2021) “Application of disk tube reverse osmosis in wastewater treatment: A review" The Science of the Total Envi ronment 792: 148291. DOI: 10.1016/j.scitotenv.2021.148291.
[33] M.T. Sturm, E. Myers, D. Schober, C. Thege, A. Ko rzin, and K. Schuhen, (2022) “Adaptable process de sign as a key for sustainability Upgrades in wastewater treatment: Comparative study on the removal of microp ollutants by advanced oxidation and granular activated carbon processing at a German municipal wastewater treatment plant" Sustainability 14(18): 11605. DOI: 10.3390/su141811605.
[34] D. Patel, A. Mudgal, V. Patel, and J. Patel. “Water desalination and wastewater reuse using integrated reverse osmosis and forward osmosis system”. In: IOP Conference Series: Materials Science and Engineer ing. 1146. 1. 2021, 012029. DOI: 10.1088/1757-899X/1146/1/012029.