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2017/4
Experimental validation of industrial CO2 sequestration scheme in underground pool of Devon field
Chemical sciences

Authors: Vadim N. KHLEBNIKOV graduated from Bashkir State University in 1979, he is Doctor of Technical Sciences, Professor of the Department of Physical and Colloid Chemistry of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of enhanced oil recovery and development of hard-to-recover oil reserves. He is author of more than 200 scientific publications. E-mail: Khlebnikov_2011@mail.ru
Aleksandr S. MISHIN graduated from National Research Nuclear University „MEPhI” in 2005. He is engineer of the Department of Physical and Colloid Chemistry of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of enhanced oil recovery and development of hard-to-recover oil reserves. He is author of more than 20 scientific publications. E-mail: aleks_mishin@mail.ru
LIANG MENG graduated from Beijing Institute of Petrochemical Technology in 2009, he is Ph.D of the Department of Physical and Colloid Chemistry of Gubkin Russian State University of Oil and Gas (National Research University). E-mail: liangmeng@mail.ru
Natalia A. SVAROVSKAYA graduated from Тomsk State University in 1971. She is Doctor of Technical Sciences, Professor of the Department of Physical and Colloid Chemistry of Gubkin Russian State University of Oil and Gas (National Research University). She is specialist in enhanced oil recovery and development of hard-to-recover oil reserves. She is author of more than 160 scientific publications. E-mail: na_sv2002@mail.ru
Natalia V. LIKHACHEVA graduated from Gubkin Russian State University of Oil and Gas. She is first-year PG student of the Department of Physical and Colloid Chemistry of Gubkin Russian State University of Oil and Gas (National Research University). Her academic interests include ecology and oil- and gas-extraction. E-mail: likhacheva.natalia.v@gmail.com

Abstract: Physical simulation of sequestration of СО2 as flue and enriched flue gas was made in the conditions of depleted reservoir filled with light crude and high-salinity water. In these circumstances it is advised to sequestrate industrial СО2 as WAG since this is an advanced method providing highly efficient displacement of residual oil and delays the breakthrough of gas. Using WAG allows to increase effective capacitance of geological trap to 25-105 %. A general procedure of sequestration of industrial greenhouse gases in geological traps is proposed

Index UDK: 502.211+622.276.344

Keywords: greenhouse gases sequestration, geological traps, depleted reservoir, water-alternated-gas injection, WAG

Bibliography:
1. Hlebnikov V.N., Zobov P.M., Hamidullin I.M. i dr. Perspektivnye regiony dlja osushhestvle- nija proektov po hraneniju parnikovyh gazov v Rossii. Bashkirskij himicheskij zhurnal, 2009, t. 16, no. 2, p. 73-80.
2. Bajmuhammetov K.S., Viktorov P.F., Gajnullin K.H., Syrtlanov A.Sh. Geologicheskoe stroenie i razrabotka neftjanyh i gazovyh mestorozhdenij Bashkortostana. Ufa: RIC ANK „Bashneft’ ”, 1997, 424 p.
3. Vafin R.V. Povyshenie jeffektivnosti tehnologii vodogazovogo vozdejstvija na plast na Alekseevskom mestorozhdenii. Neftepromyslovoe delo, 2008, no. 2, p. 33-35.
4. Vafin R.V. Metod regulirovanija tehnologiej vodogazovogo vozdejstvija na plast. Neftepro-myslovoe delo, 2008, no. 2, p. 30-32.
5. Zacepin V.V., Maksutov R.A. Sovremennoe sostojanie promyshlennogo primenenija tehno-logij vodogazovogo vozdejstvija. Neftepromyslovoe delo, 2009, no. 7, p. 13-21.
6. Polishhuk A.M., Hlebnikov V.N., Mishin A.S. i dr. Jeksperimental’noe issledovanie me-hanizma fil’tracii vodogazovyh smesej. Vestnik CKR Rosnedra, 2012, no. 6, p. 8-14.
7. Ulavlivanie i hranenie dvuokisi ugleroda. Special’nyj doklad MGJEIK. Mezhpravitel’stven-naja gruppa jekspertov po izmeneniju klimata, 2005. ISBN 92-9169-419-3. URL: https://ipcc.ch/pdf/ special-reports/srccs/srccs_spm_ts_ru.pdf (data obrashhenija: 09.10.2016).

2016/1
Assessment of oil-displacing ability of gas under thermogas oil recovery
Geosciences

Authors: Vadim N. KHLEBNIKOV graduated from Bashkir State University in 1979. He is Doctor of Technical Sciences, Professor of the Department of Physical and Colloid Chemistry of Gubkin Russian State University (National Research University) of Oil and Gas. He is specialist in the field of enhanced oil recovery and development of hard-to-recover oil reserves. He is author of more than 200 scientific publications. E-mail: Khlebnikov_2011@mail.ru
Aleksandr S. MISHIN graduated from National Research Nuclear University «MEPhI» in 2005. He is Engineer of the Department of Physical and Colloid Chemistry of Gubkin Russian State University (National Research University) of Oil and Gas. He is specialist in the field of enhanced oil recovery and development of hard-to-recover oil reserves. He is author of more than 20 scientific publications. E-mail: aleks_mishin@mail.ru
MENG Liang graduated from Beijing Institute of Petrochemical Technology in 2009, he is Ph.D student of the Department of Physical and Colloid Chemistry of Gubkin Russian State University (National Research University) of Oil and Gas. Research interests: oil and gas production. E-mail: liangmeng@mail.ru
Natalya A. SVAROVSKAYA graduated from Тomsk State University in 1971. She is Doctor of Technical Sciences, Professor of the Department of Physical and Colloid Chemistry of Gubkin Russian State University (National Research University) of Oil and Gas. She is specialist in the field of petroleum geology and tertiary oil recovery. She is author of more than 160 scientific publications.
E-mail: na_sv2002@mail.ru

Abstract: A study was conducted to determine oil displacing ability of gas agent produced from in-situ transformation of air during thermal stimulation of light oil reservoirs. It is shown that the oil displacing characteristics of the gas agent of thermos-gas EOR method are close to those of fatty associated petroleum gas in high temperature reservoirs of light oil. It has also been found that the use of core formation models in flooding experiments (according to OST 39-195-86) does not allow to fully reveal the efficiency of miscible gas oil-displacing agents

Index UDK: УДК 622.276.6

Keywords: enhanced oil recovery, miscible displacement, thermos-gas oil recovery method, physical simulation of oil displacement

Bibliography:
1. Kuramshin R.M. Osobennosti geologicheskogo stroeniya i tehnologii razrabotki yurskih otlojenii Nijnevartovskogo svoda [Features of the geological structure and development technology of Jurassic sediments Nizhnevartovsk dome]. Moscow, RMNTK Nefteotdacha Publ., 2002, 107 p.
2. Bagautdinov A.K., Markov S.L., Belevich G.K. and et al. Geologiya i razrabotka krupneishih i unikalnih neftyanih i neftegazonosnih mestorojdenii Rossii [Geology and development of large unique oil and gas fields in Russia]. Moscow, VNIIOENG Publ., 1996, 352 p.
3. Bokserman A.A. and Yambaev M.F. The method of injection and in situ transformation of air in fields of light oil. Proc. 12 th European Symposium on improved Oil Recovery. Kazan, Russia, 2003 (in Russian).
4. Yambaev M.F. Osnovnie osobennosti termogazovogo metoda uvelicheniya nefteotdachi primenitelno k usloviyam slojnopostroennih kollektorov (na osnove chislennogo modelirovaniya). Dokt, Diss. [The main features of thermal gas EOR applied in the conditions of complex reservoirs (on the basis of numerical modeling). Doct, Diss.], Moscow, 2006, 153 p.
5. Khlebnikov V.N. and Vezhnin S.A. Perspektivi primeneniya termogazovogo metoda povisheniya nefteotdachi v usloviyah yurskih plastov mestorojdenii OAO «Tomskneft» [Prospects of application of thermo-gas method for enhanced oil recovery in the conditions of Jurassic reservoir in fields «Tomskneft»]. Trudy Obedinennogo centra issledovanii i razrabotok «Perspektivi tehnologii neftegazovoi industrii» [Proc. of the Joint research and development center «Prospects of technology in the oil and gas industry»], 2006, no. 2, p. 79-84.
6. Kumar V.K., Gutierrez C., Cantrell C. 30 Years of Successful High-Pressure Air Injection: Performance Evaluation of Buffalo Field, South Dakota. Journal of Petroleum Technology, 2011, vol. 63, no. 01, p.50-53.
7. Khlebnikov V.N., Zobov P.M., Antonov S.V., Ruzanova Yu.F. Research on thermos-gas method for oil extraction. Kinetic laws of oil autoxidation of Jurassic age reservoir. Bashkirskii Khimicheskii Zhurnal [Bashkir Chemical Journal], 2008, vol. 15, no. 4, p. 105-110 (in Russian).
8. Khlebnikov V.N., Zobov P.M., Antonov S.V., Ruzanova Yu.F., Bakulin D.A. Research on thermo-gas method for oil extraction. Influence of sodium bicarbonate on the kinetic laws of light oil autoxidation. Bashkirskii Khimicheskii Zhurnal [Bashkir Chemical Journal], 2009, vol. 16, no. 1, p. 65-71 (in Russian).
9. Khlebnikov V.N., Zobov P.M., Antonov S.V., Bakulin D.A., Gushina Yu.F. and Nisku- lov E.K. Comparison of the kinetic laws of autooxidation of oil and solid organic material in rocks of Bazhenov suite. Bashkirskii Khimicheskii Zhurnal [Bashkir Chemical Journal], 2011, vol. 18, no. 4, p. 87-92 (in Russian).
10. Khlebnikov V.N., Mishin A.S., Zobov P.M., Antonov S.V., Bakulin D.A., Bardin M.E. and Niskulov E.K. Simulation of chemical steps in thermo-gas enhanced viscous oil of reservoirs PK Cenomanian horizon. Bashkirskii Khimicheskii Zhurnal [Bashkir Chemical Journal], 2012, vol. 19, no. 3, p. 12-16 (in Russian).
11. Aizikovich O.M., Bulygin M.G., Korablev L.I. The thermal effect of oxidation reaction in the wet in-situ combustion. Neftepromyslovoe delo and transport nefte [Petroleum engineering and oil transport], 1985, no.11, p. 4-6 (in Russian).
12. Yannimaras D.V., Sufi A.H., Fassihi M.R. The Case for Air Injection into Deep Light Oil Reservoirs. Proc. 6th European IOR-Simposium. Stavanger, Norway, 1991.
13. Lake L.W. Enhanced oil recovery. Englewood Cliffs, New Jersey, Prentice Hall Publ., 1989, 449 p. (Russ. ed.: Osnovi metodov uvelicheniya nefteotdachi, 2004, 449 p. Available at: www.oil-info.ru/content/view/148/59 ).
14. Polishchuk A.M., Khlebnikov V.N. and Gubanov V.B. Using slim models for the physical simulation of oil displacement processes by miscible agents. Part 1. Methodology of experiment. Neftepromyslovoe delo  Petroleum engineering, 2014, no. 5, p. 19-24 (in Russian).
15. Khlebnikov V.N., Gubanov V.B. and Polishchuk A.M. Using slim models for the physical simulation of oil displacement processes by miscible agents. Part 2. Evaluation of the possibility of using standard flooding equipment for the implemention of slim methodology. Neftepromyslovoe delo. Petroleum engineering, 2014, no. 6, p. 32-38 (in Russian).
16. Industry Standard OST-39-195-86. Oil. The method of determining the coefficient of oil displacement by water in the laboratory. Moscow. The Ministry of Petroleum Publ., 1986, 20 p. (in Russian).
17. Yellig W.F., Metcalfe R.S. Determination and Prediction of CO2 Minimum Miscibility Pressures. Journal of Petroleum Technology, 1980, vol. 32, no. 1, pp. 160-168.

2009/2
Colloid reagent influence to solidity contact of cement stone with metal
Drilling and development of hydrocarbon fields

Authors: Vadim Nikolaevich KHLEBNIKOV was born in 1957. Doctor of Technical Sciences, professor of physical and colloidal chemistry chair of Gubkin Russian State University of Oil and Gas, head of petroleum production laboratory “YRD-Center” (Moscow). He is the author of more than 150 scientific works, including 1 monograph and 25 patents. Е-mail: Khlebnikov@yrd.ru
Pavel Mikhailovich ZOBOV was born in 1956. In 1979 he graduated from the Ufa oil institute, deputy head of the laboratory of the “URD-Center”, the author of 47 publications including 5 patents.
Sergey Vladimirovich ANTONOV was born in 1981. In 2003 he graduated from Chemical faculty of M.V. Lomonosov Moscow State University, scientific associate of the laboratory of oil recovery of “Incorporated center of research and development” Ltd., the co-author of 5 scientific publications.
Alexandr Sergeevich MISHIN was born 1979. In 2000 he graduated from Engineering-physical institute, the scientific associate of the laboratory of oil recovery of “Incorporated center of research and development” Ltd., the co-author of 5 scientific publications.
Yuliya Fedorovna GUSHCHINA was born in 1985. In 2008 she graduated from Gubkin Russian State University of Oil and Gas. The scientific associate of the laboratory of oil recovery of “Incorporated center of research and development” Ltd., the co-author of 5 scientific publications.
Vladimir Arnoldovich VINOKUROV was born in 1950. In 1972 graduated from Gubkin Moscow Institute of Oil and Gas Industry (now Gubkin Russian State University of Oil and Gas). Doctor of Chemistry, professor, Head of Physical and Colloidal Chemistry Chair of Gubkin Russian State University of Oil and Gas. Author of 250 publications. Е-mail: vinok_ac@mail.ru

Abstract: In the result of laboratory research and development work it is shown, that stabilized colloid reagent is the effective additive to the cement slurry for well-casing in the conditions of Far North

Index UDK: 622.24

Keywords: oil-well cement, colloid reagent, superplastificator, adhesion, contact solidity

Bibliography: