Autonomous Ecologically Safe Installation for Sea Water Desalination
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Bauman Moscow State Technical University, RUSSIA
Vladimir I. Krylov   

Bauman Moscow State Technical University, Moscow, Russia
Online publication date: 2017-09-27
Publication date: 2017-09-27
Eurasian J Anal Chem 2017;12(Interdisciplinary Perspective on Sciences 7b):1045–1057
Urgency of the research: Urgency of the issue under discussion is caused by fresh water deficiency. Goal of the research: The goal is to develop a combined wind power unit for seawater desalination and a technology for the reverse osmosis concentrate process into product salts in the arid climate. Methods of the research: The leading method of the research is the testing of the wind power unit and the modeling of the reverse osmosis concentrate process. Results of the research: The article describes the main results of the literature analysis, represents the flowchart of the combined wind power unit for seawater desalination, the main results of the unit test, the flowchart of the basin management for the reverse osmosis concentrate recycling into product salts. Practical significance of the research: The further implementation of the project would allow to obtain drink water from seawater, as well as water for agriculture and product salts, which prevents reverse osmosis concentration discharge into the environment. The obtained results can be used to further improve water desalination equipment and to develop desalination plants powered by renewable energy sources; to modernize existing independent wind power units.
Danilov-Danilyan, V. I. (2009). World water resources and prospects of the Russian water complex. Moscow: OOO “Printing Levko”, Institute for Sustainable Development.
Perelet, R. A. (2010). Water scarcity and water efficiency economy. Moscow: Partnership scientific knowledge KMK.
Likhacheva, A. B. (2013). The issue of fresh water as a structural factor in the global economy. Higher School of Economics Economic Journal, 3, 533-563.
Yeliseyev, Y. S. (2007). Optimization of applications of various methods of seawater desalination. Water preparation and water treatment equipment, 1, 2-7.
IWRA. (2010). Water International, 25(1), 117-126.
Bagrov, V. V, Kamrukov, A. S., & Ksenofontov, B. S. (2010). Water. Effects and Technology. Moscow: OOO SIC “Engineer”.
Panteleev, A. A., Ryabchikov, B. E., & Horunzhiy, O. V. (2012). Technology of membrane separation in the industrial water treatment. Moscow Delhi plus.
Basque, V. N., & Kamyanchuk, A. B. (2008). Agricultural Community of the XXI century: ways of development. Irbit: ID “Printed Wave”.
Cherdymova, E. I., Kuznetcov, V. A., Machnev, V. Y., Solovova, N. V., Sarbaeva, I. Yu., & Masalimova, A. R. (2017). Eco-Vocational Consciousness Formation Model of a Specialist in Modern Mega Polis. Eurasian Journal of Analytical Chemistry, 12(A Multidisciplinary Approach to science 5b), 493-507.
Kamrukov, A. S. (1991). Experimental research of radiation- plasmodinamic devices of laboratory and industrial purpose. Moscow: Energoatomisdat.
Wekhof, A. (1991). Treatment of Contaminated Water, Air and Soil With UV Flashlamps. Enviropmental Progress, 10(4), 241-247.
Arkhipov, V. P. (1993). A disinfection method for sterilization of exposed objects surfaces, liquids, and gases. No.2001629 Russian Federation. Moscow: Nauka.
Arkhipov, V. P. (1996). The new technology of deep UV water purification and disinfection. Coversion, 6, 46-50.
Kowalski, W. J. (2003). Immune Building Systems Technology. New York: McGraw - Hill.
Kamrukov, A. S. (2003). New biocidal ultraviolet technology and devices for sanitation, microbiology and medicine. Life safety, 1, 32-40.
Potapchenko, N. G. (1991). The use of ultraviolet radiation in water disinfection. Chemistry and water technology, 13(12), 1117-1129.
Harris, G. D., Adams, V. D., & Sorensen, D. L. (1987). Ultraviolet inactivation of selected bacteria and viruses with photoreactivation of the bacteria. Water Research, 21(6), 687-692.
Vekhov, A. (2000). The Desinfection with Flash Lamp. PDA J. of Pharmaceutical & Technology, 54(3), 264-276.
Arkhipov, V. P., Kamrukov, A. S., & Shashkovsky, S. G. (1993). A method for disinfection and sterilization of exposed surfaces of objects, liquids, and air. Russian Patent No.2001629, 1993 (also RF patents No.2001882, 2008042, 2031659, 2031850, 2031851, 2088286, 2137365, 2184579).
Rasev, A. S. (1990). Drying of wood. Moscow: Higher School of Economics.
Shikheyeva, L. V., & Zyrianov, V. V. (1978). Sodiumsulfate. Property and production. Leningrad: Chemistry.
Carta, J. A., Gonzalez, J., Cabrera, P., & Subiela, V. J. (2015). Preliminary experimental analysis of a small-scale prototype SWRO desalination plant, designed for continuous adjustment of its energy consumption to the widely varying power generated by astand-alone wind turbine. Applied Energy, 137, 222-239.
Arkhipov, V. P., Bagrov, V. V., & Zhelaev I. A. (2016). Patent for PM 161 633 of the Russian Federation IPC C02F 1/32. Automatic water disinfection unit, 12, 1-16.
Drinking water. (2002). Hygienic requirements for water quality of centralized drinking water supply systems. Quality control. Hygienic requirements to provision. Moscow: IIMR.
Pozin, M. E. (1974). Technology of mineral salts. Leningrad: Chemistry.
Mosin, A. B. (2011). Seawater desalination plants. Journal SOK, 11, 22-25.