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2018/1
Chemical dispersion technology application during underwater oil pipelines accidents in the Arctic
Chemical sciences

Authors: Irakly A. MERITSIDI graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1987. He is Candidate of Technical Sciences, Associate Professor of the Department of Machines and Equipment of Oil and Gas Wells of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of localization of oil spills and oil products and author of more than 50 scientific papers. He has been awarded 7 gold and 1 silver medals at international exhibitions for his inventions. E-mail: iameritsidis@rambler.ru
Konstantin Kh. SHOTIDI graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1966. He is Candidate of Technical Sciences, Professor of the Department of Thermodynamics and Thermal Engines at Gubkin Russian State University of Oil and Gas (National Research University). He is the author of more than 100 scientific, educational and methodical works and patents on thermal methods of influence on oil formation, research of thermophysical properties of rocks, applied questions of thermodynamics and heat transfer. E-mail: chotidi.k@gubkin.ru
Iraklis I. MERICIDI graduated from Gubkin Russian State University of Oil and Gas (National Research University) in 2014. He is Assistant Lecturer of the Department of Thermodynamics and Thermal Engines, Gubkin Russian State University of Oil and Gas (National Research University). He is the author of scientific works on engineering and technology of repair of underwater pipelines, localization and liquidation of oil spills in case of accidents. He is participant of international youth scientific conferences.
E-mail: fokasi@rambler.ru

Abstract: The article is devoted to the use of chemical dispersion technology during the underwater oil pipelines accidents in the Arctic. Dependences of dispersion efficiency on salinity, viscosity, temperature and limitations of the use of dispersion depending on environmental conditions are given. The actuality of the use of underwater dispersion in the Arctic conditions is considered

Index UDK: 551.46, 504.05, 622.692.48; 622.692.4.07

Keywords: оil, spills, chemical dispersion, underwater dispersion, dispersants, the Arctic conditions, underwater pipelines

Bibliography:
1. Mazlova E.A., Meritsidi I.A. „Analysis and applicability of methods for liquidating oil and oil products spills in the Arctic on the continental shelf”, report of the research work of the Federal State Unitary Enterprise „REA” of the Ministry of Energy of the Russian Federation, 2014, 152 p. (In Russian, unpublished).
2. Meritsidi I.I., Shotidi K.X. Windows of possibility determination of methods for oil spills localisation during the offshore pipelines accidents. Transport i hranenie nefteproduktov i uglevodorodnogo syr’ja, 2015, no. 2, p. 30–33 (in Russian).
3. Technique and technology of л of localization and liquidation of emergency oil spills and oil products. Directory. Under the general editorship. I.A. Meritsidi, St. Petersburg, NPO „Professional”, 2008, 819 p.
4. ExxonMobil. Prevention and elimination of marine oil spills in arctic conditions and emergency preparedness. Available at: http://cdn.exxonmobil.com/~/media/russia/files/arctic/arctic-osr_russian-final.pdf
5. SIEP BV. Dr. Viktorija Brozhe. Modern technologies for liquidation of oil and oil products spills in the marine environment. Available at: http://new.groteck.ru/images/catalog/32772/eaa9de34a 3b4bd6f 81b973d6f40bc5ac.pdf
6. Belore R.C., Trudel K., Mullin J.V. and Guarino A. Large-scale cold water dispersant effectiveness experiments with Alaskan crude oils and Corexit 9500 and 9527 dispersants. Marine Pollution Bulletin, 58, 2009, p. 118-128.
7. Brandvik P.J., Moldestad M.Q. and Daling P.S. Laboratory testing of dispersants under Arctic conditions. In: Proceedings Arctic and Marine Oilspill Program (AMOP) Technical Seminar, 1992, no. 15, p. 123–134. Environment Canada, Ottawa.
8. Brown H.M. and Goodman R.H. The use of dispersants in broken ice. In: Proceedings Arctic and Marine Oilspill Program (AMOP) Technical Seminar, 1996, no. 19, vol. 1, p. 453–460. Environment Canada, Ottawa.
9. CEDRE. Using dispersants to treat oil slicks at sea. Available: http://www.cedre.fr/ en/publi-cation/dispersant/dispersant.php.
10. IPIECA-IOGP 2015. Dispersants: surface applications Available: http://www.oilspillres-ponseproject.org/wp-content/uploads/2017/01/Dispersants-surface_application_2016.pdf
11. Lewis A. and Daling P.S. Oil in ice: A review of studies of oil spill dispersant effectiveness in Arctic conditions (JIP Project 4, Act. 4.11). Report No. 11: SINTEF A 16086 Report Publication, 2007, 22 p.
12. Owens C. and Belore R. Dispersant effectiveness testing in cold water and brash ice. In: Proceedings Arctic and Marine Oilspill Program (AMOP) Technical Seminar, 2004, no. 27, vol. 2, p. 819–841. Environment Canada, Ottawa.
13. Sørstrøm S.E., Brandvik P.J., Buist I., Daling P., Dickins D., Faksness L-G., Potter S., Rasmussen J.F. and Singsaas I. Joint industry program on oil spill contingency for Arctic and ice-cove- red waters: Summary Report. SINTEF Report A14181. SINTEF. Trondheim, Norway, 2010. www.sintef.no/Projectweb/JIP-Oil-In-Ice/Publications/.

2009/4
Formation and development of the department of thermal dynamics and heat engines
Design, construction and operation of pipeline transport

Authors: Alexey S. LOPATIN (b. 1956), graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1979, Doctor of technical sciences, prof, head of the Dept of Thermal Dynamics and Heat Engines of Gubkin Russian State University of Oil and Gas. He is the author of over 200 scientific publications. E-mail: lopatin.a@gubkin.ru
Borisynamics P. PORSHAKOV (b. 1928), graduated from Gubkin Moscow Oil Institute in 1951, Doctor of technical sciences, prof. of the Dept. of Thermal Dynamics and Heat Engines of Gubkin Russian State University of Oil and Gas. He is the author of over 200 scientific publications. E-mail: thermo@gubkin.ru
Konstantin Kh. SHOTIDI (b. 1942), graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1966, Doctor of technical sciences, prof, deputy head of the Dept of Thermal Dynamics and Heat Engines of Gubkin Russian State University of Oil and Gas. He is the author of 76 scientific publications. E-mail: chokonst@gubkin.ru

Abstract: A brief historical overview of the development of the Department of thermal dynamics and heat engines is presented. The stages of formation and main trends of the development of the scientific school of N.I. Belokon «Power Engineering of Pipeline Transportation of Natural Gas» are described

Index UDK: 536+621.4

Keywords: Belokon N.I., power engineering of pipeline transportation, department of thermal dynamics and heat engines, scientific school, personnel training

Bibliography:

2009/4
Environmental efficiency of gas-turbine units of gas industry
Industrial and environmental safety, occupational safety and health

Authors: Konstantin Kh. SHOTIDI (b. 1942), graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1966, Doctor of technical sciences, prof, deputy head of the Dept of Thermal Dynamics and Heat Engines of Gubkin Russian State University of Oil and Gas. He is the author of 76 scientific publications. E-mail: chokonst@gubkin.ru
Eduard A. MICKAELYAN (b. 1937), graduated from Azizbekov Azerbaijan Oil and Gas Institute in 1959, Candidate of technical sciences, assistant prof. of the Dept. of Thermal Dynamics and Heat Engines of Gubkin Russian State University of Oil and Gas. He is the author of over 275 scientific publications. E-mail: gazovik@gmail.com

Abstract: Hazardous emissions of a gas-turbine unit are compared with those of other heat engines and furnace plants. Measures to reduce carbon and nitrogen oxides concentrations in the gases emitted from a gas-turbine unit are considered. An example of calculating environmental parameters in the process of gas-turbine operation is given. Economic appraisal of upgraded units with respect for hazardous emissions is presented.

Index UDK:

Keywords: environmental friendliness of heat engines, gas-turbine units

Bibliography: