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Title: Environment-Friendly Technology of Airport’s Sewerage
Authors: Шаманський, Сергій Йосипович
Бойченко, Сергій Валерійович
Keywords: Airport
Waste management
Issue Date: 2018
Publisher: Springer International Publishing
Citation: Shamanskyi S., Boichenko S. (2018) Environment-Friendly Technology of Airport’s Sewerage. In: Karakoç T., Colpan C., Şöhret Y. (eds) Advances in Sustainable Aviation. Springer, Cham. Shamanskyi, S., & Boichenko, S. (2017). Environment-friendly technology of airport's sewerage. Advances in sustainable aviation (pp. 161-175) doi:10.1007/978-3-319-67134-5_11 Retrieved from
Series/Report no.: Advances in Sustainable Aviation;
Abstract: There is a proposed new environmentally friendly technology of airport’s sanitary sewage water treatment, which allows improving the quality of the treated sewage water, diminishing harmful impacts on environment during sewage sludge utilization, and obtaining additional amount of alternative energy sources. Within the bounds of this technology, there is a proposal to organize two additional processes. The first one is a process of microalgae cultivation, using mechanically and biologically treated sewage water as a growing medium. For cultivation, there is a proposed culture of microalgae with high lipid content. It allows improving the quality of treated water and producing liquid biofuel out of the cultivated algae. A new construction of photobioreactor is proposed there. This construction allows intensifying the cultivation process. The second one is the process of anaerobic digestion of sewage sludge along with biomass, which remains as waste product after biofuel production out of cultivated microalgae. The digestion is proposed to conduct in special installations, using new method to organize it. The method allows obtaining environmentally friendly organic fertilizer, biogas with increased methane content and carbon dioxide, which can be used for microalgae cultivation process.
Description: 1. Tiruneh, A. T., Fadiran, A. O., & Mtshali, J. S. (2014). Evaluation of the risk of heavy metals in sewage sludge intended for agricultural application in Swaziland. International Journal of Environmental Sciences, 5(1), 197–216. 2. Akpor, O. B. (2011). Wastewater effluent discharge: Effects and treatment processes/3rd International Conference on Chemical. Biological and Environmental Engineering IPCBEE, 20(2011), 85–91. 3. Alrawi, R., Ahmad, A., Norli, I., & AK, M. (2010). Methane production during start-up phase of mesophilic semi-continues suspended growth anaerobic digester. International Journal of Chemical Reactor Engineering, 8(8), 89. 4. Altas, L. (2009). Inhibitory effect of heavy metals on methane-producing anaerobic granular sludge. Journal of Hazardous Materials, 162, 1551–1556. 5. Babaev, V. N., Goroch, N. P., & Korinko, I. V. (2011). Power budget of methane formation during mesophilous anaerobic decomposition of organic parts of wastes. Eastern-European Journal of Advanced Technology, 4(6), 59–65. (In Russian). 6. Barskiy, E. L., Shandieva, I. O., Savanina, J. V., et al. (2011). Effect of melafen on development of cyanobacteria cultures and green mikroalgae under stress conditions. Proceedings of the Moscow State University, 1, 15–20. (In Russian). 7. Danilovich, D. A., Kozlov, M. N., Kevbrina, M. V., & Gusjev, D. V. (2009). Influence of sewage water sludges pretreatment on completeness of methane fermentation processes. Water: Technologies, Materials, Equipment, Ecology, 2, 24–26. (In Russian). 8. Gersberg, R. M., Elkins, B. V., Lyon, S. R., & Goldman, C. R. (1986, March). Role of aquatic plants in wastewater treatment by artificial wetlands. Water Research, 20(3), 363–368. 9. Gjunter, L. I., & Goldfarb, L. L. (1991). Methanetanks. M.: Strojizdat. 280 p. (In Russian). 10. Healy, A. M., & Cawleyb. (2002). Nutrient processing capacity of a constructed wetland in Western Ireland. Journal of Environmental Quality, 31, 1739–1747. 11. Jakovlev, S. V., Karelin, J. £., Zhukov, £. I., & Kolobanov, S. -. (1975). Sewerage. ¯oscow: Strojizdat. 632 p. (In Russian). 12. Kadam, A., Oza, G., Nemade, P., Dutta, S., & Shankar, H. (2008). Chemosphere, 71, 975–981. 13. Kovalev, V. V., Ungurjanu, D. V., & Kovaleva, O. V. (2012). Theoretical and practical aspects of improving processes of biogas technology. Problems of Regional Energetics, 1, 102–114. (In Russian). 14. Kramariova, U. S. (2011). Prospects of application of tetrasodium salt of ethylene diamine tetraacetate as an extractant of heavy metals from urban sewage water sludges. Medical Prospects, XVI/4(11), 127–129. (In Ukrainian). 15. Liao, B. Q., Kraemer, J. T., & Bagley, D. M. (2006). Anaerobic membrane bioreactors. Application and research directions. Science Technology, 36, 489–530. 16. Möller, U. (1988). Entseuchung von Klarschlam. Eine Standartbestimmung. Korrespondenz Fbwasser, 1, 24–30. (In German). 17. Pavliukh, L. I., & Boichenko S. V. (2012). Application of natural raw plant materials based sorbents in the purification systems of oil contaminated waters of aviation enterprises (Vol. 3, pp. 4.3.48–4.3.50). Proceedings the Fifth World Congress [“Aviation in the XXI-st Century”]. Kiev, 25–27 September. 18. Pereira, M. A., Cavaleiro, A. J., Mota, M., & Alves, M. M. (2003). Accumulation of long chain fatty acids onto anaerobic sludge under steady state and shock loading conditions: Effect on acetogenic and methanogenic activity. Water Science Technology, 48, 33–40. 19. Predzimirska, L. M. (2015). Cavitational purification of natural and sewage waters from organic and biological contaminations: aref. of PhD thesis. Ivano-Frankivsk. 21 p. (In Ukrainian). 20. Gaber, S. E., Rizk, M. S., & Yehia, M. M. (2011, March 31). Extraction of certain heavy metals from sewage sludge using different types of acids. Boikemistry, 23(1), 41–48. 21. Sorokina, K. N., Jakovlev, V. A., Piligaev, A. V., et al. (2012). Potential of using microalgae as a raw material for bioenergy sector. Catalysis in Industry, 2, 63–72. 22. Shamanskyi, S. I. (2015). Continuously working installation for solar energy bioconversion. Science Intensive Technologies, 2(26), 115–119. (In Ukrainian). 23. Shamanskyi, S. I., & Boichenko, S. V. (2015). Energy efficient and environmental friendly technology of stabilizing of airline enterprises’ wastewater sludges. East European Journal of Advanced Technology, 5/8(77), 39–45. (In Ukrainian). 24. Shamanskyi, S. I., & Nestorjak, D. M. (2012). Bioconversion of solar energy as a perspective direction in alternative energy (pp. 371–372). “Green Energy”. International theoretical and practical conference: 17–19 July 2012, Kyiv. 25. Trakhunova, I. A. (2014). Increasing efficiency of anaerobic treatment of organic wastes in a methane tank with hydraulic agitation on the basis of numerical experiment. aref. of PhD thesis. Kazan’. 19 p. (In Russian). 26. Volova, µ. G. (1999). Biotechnology. Novosibirsk: Publishing House of Siberian Branch of Russian Academy of Science. 252 p. (In Russian). 27. Zieminski, K., & Fr ˛ ´ ac, M. (2012). Methane fermentation process as anaerobic digestion of biomass: Transformations, stages and microorganisms. African Journal of Biotechnology, 11(18), 4127–4139.
ISBN: 978-331967134-5;978-331967133-8
Appears in Collections:Публікації у наукових виданнях співробітників кафедри екології

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