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2017/3
Study of biopolymer-drilling fluid influence on core-samples permeability and estimation of enzyme-breaker efficiency
Geosciences

Authors: Daria M. GUSEVA is currently a postgraduate student at the Drilling Department of Gubkin Russian State University of Oil and Gas (National Research University). She specializes in drilling and completion fluids. E-mail: daria.guseva@yandex.ru
Sergey A. KRAVTSOV graduated from Gubkin Russian State University of Oil and Gas in 2008 as a Candidate of Technical Sciences. He has published 7 research papers. E-mail: sergey.kravtsov2@bakerhughes.com
Servgey V. TEMNIK graduated from Gubkin Russian State University of Oil and Gas in 2006. He is specialist in drilling and completion fluids. E-mail: temnserv@gmail.com

Abstract: Penetration of the drilling mud filtrate, the solid phase and the drilling mud proper in the process of well-completion reduces the filtration and capacitance properties of the productive formation. One way to solve this problem is to use chemical agents to destroy the components of the drilling mud and restore the original reservoir quality. The paper describes a lab experiment carried out to justify the application of the enzyme-breaker filter cake clean-up system at Suzun field. The efficiency of the enzyme-breaker application for a uniform and full filter cake clean-up is evaluated. The suggestions for pilot tests are made

Index UDK: 622.245.514

Keywords: enzyme, return permeability, filter cake clean-up

Bibliography:
1. Varfolomeev S.D. Chemical Enzymology: Manual. M.: Publishing office «Academy», 2005, 480 p.
2. Hisham A. Nasr-El-Din, Mohammed Badri Al-Otaibi, Abdulqader A. Al-Qahtani, Omar A. Al-Fuwaires. Filter-Cake Cleanup in MRC Wells Using Enzyme/Surfactant Solutions, SPE, 2006.
3. Thomas E. Suhy, Ramon P. Harris Application of Polymer Specific Enzymes To Clean Up Drill-In Fluids, SPE, 1998.

2017/3
Prediction of natural gas values imbalance
Geosciences

Authors: Farit G. TUKHBATULLIN was born in 1950, graduated from the Ufa Oil Institute in 1972. He is Doctor of Technical Sciences, professor of the Department of Petroleum Products and Natural Gas Supply of Gubkin Russian State University of Oil and Gas (National Research University), Member of the Russian Academy of Engineering and Technology. He is author 21 inventions and 170 scientific papers. E-mail: ellkam@mail.ru
Dmitriy S. SEMEICHENKOV was born in 1993. Не graduated from Gubkin Russian State University of Oil and Gas in 2015. He is graduate student of the Department of Petroleum Products and Natural Gas Supply of Gubkin Russian State University of Oil and Gas (National Research University). He is author of 3 publications. E-mail: d.semeichenkoff@yandex.ru
Tagir F. TUKHBATULLIN was born in 1976. Нe graduated from the Ufa Oil Institute in 1988. Candidate of Technical Sciences, Deputy Head of the Department of 310/2/1 310 PJSC «Gazprom». Research interests: more efficient management of technological modes of transport of gas. He is author of 15 publications. E-mail: tagtuh@mail.ru

Abstract: The need for specialized software and programming and computing suites ), to forecast the magnitude of the imbalance of natural gas when it is sold to end users, as well as to enter on-line statistically accumulated information in order to increase the effectiveness of managerial decisions in the dispatch administration of the Unified Gas Supply System is demonstrated

Index UDK: 519.237.5:62.503.56

Keywords: gas imbalance, dispatch administration, commercial metering of gas, forecasting, regression analysis

Bibliography:
1. Gmurman V.E. Probability theory and mathematical statistics: Textbook for high schools. M.: Higher School, 2003, 479 p. (in Russian).
2. Sukharev M.G. Forecasting methods: Textbook. M.: Russian State University of Oil and Gas 2009, 208 p. (in Russian).
3. STO Gazprom 5.37-2011 uniform technical requirements for equipment flow measurement units and the amount of natural gas used in JSC «Gazprom» (in Russian).
4. STO Gazprom 5.32-2009 Organization of natural gas measurement (in Russian).
5. STO Gazprom 2-3.5-454-2010 rules of operation of gas mains (in Russian).
6. Hvorov G.A., Kozlov S.I., Akopova G.S., A.A. Evstifeev. Reduction of losses of natural gas for transportation through main pipelines of JSC «Gazprom». Gas industry, 2013, no. 12, р. 66-69 (in Russian).
7. Pavlovsky M.A. Application of mathematical statistics to analyze the reasons for the imbalance in the transport of natural gas pipeline transmission system. Electronic scientific journal «Oil and gas business», 2012, no. 1, p. 69-74 (in Russian).
8. Andriishin M.P., Igumentsev E.A., Prokopenko E.A. Linear trends in the diagnosis of the gas balance. Aerospace technics and technology, 2008, no. 10 (57), p. 213-217 (in Russian).
9. Andriishin M.P., Igumentsev E.A. Dynamics of indicators of statistical reporting gas imba- lance. Materialy IX Megdunarodnoi naychno-texnicheskoi konferenzii «Metrologiya — 2014», g. Xar’kov, 15-17 oktyabrya, p. 427-430 (in Russian).

2017/3
Scientific basis of thermal fields formation and prospects of thermodynamic methods to assess offshore oil and gas structures reliability
Technical sciences

Authors: Ivan V. STAROKON’ graduated from Gubkin Russian State University of Oil and Gas in 2001. He is Candidate of Technical Sciences, Head of the Department of Automated Design of Oil and Gas Industry Structures of Gubkin Russian State University of Oil and Gas (National Research University). He is sate expert of the for Industrial Safety of the Federal Service for Ecological, Technological and Nuclear Supervision of the Russian Federation. He is author of more than 80 scientific publications.
E-mail: starokon79@mail.ru

Abstract: The offshore oil and gas structures are exposed to solar radiation, which leads to the change of their thermal state. This brings about various effects such as thermal stresses and deformation or inhomogeneity of the thermal state in the areas with defects. The article proposes a methodology for assessing the dynamics of formation of thermal fields caused by solar exposure. The technique enables to model the processes of heating and cooling of offshore oil and gas structures, which in turn will allows to adjust the assessment of their stress-strain state and to develop a method to detect defects of different origin on the basis of thermal diagnostics

Index UDK: 622.242.422:622.276.04:622.279.04

Keywords: offshore oil and gas structures, fatigue cracks, restoredweld joint, life assessment, thermal diagnostics, defects

Bibliography:
1. Borodavkin P.P. Morskie neftegazovye sooruzheniya: uchebnik dlya vuzov. CHast’ 1. Konstruirovanie. M.: OOO «Nedra-Biznescentr», 2006, p. 555.
2. Matveev L.T. Kurs obshchej meteorologii. Fizika atmosfery. L.: Gidrometeoizdat, 1984, p. 506.
3. Samojlov D.V. Raschet velichiny postupleniya teploty ot solnechnoj radiacii na poverhnost’ Zemli: metodicheskie ukazaniya/Pod red. YU.V. Peshti. M.: Izdatel’stvo MGTU im. N.EH. Baumana, 2006, p. 20.
4. Starokon’ I.V. Osnovy teorii i praktiki obrazovaniya ustalostnyh treshchin na morskih neftegazovyh sooruzheniyah. Sovremennye problemy nauki i obrazovaniya, 2012, no. 4.
5. Starokon’ I.V. O rezul’tatah chislenno-analiticheskogo modelirovaniya vozdejstviya peremennyh i uslovno stacionarnyh temperaturnyh polej na razvitie ustalostnyh treshchin morskih neftegazovyh sooruzhenij (MNGS). Fundamental’nye issledovaniya, 2013, no. 1 (ch. 1), p. 153-158.
6. Starokon’ I.V. Metodika ocenki vozdejstviya solnechnogo izlucheniya na temperaturnoe sostoyanie morskih stacionarnyh platform. Sovremennye problemy nauki i obrazovaniya, 2014, no. 2.
7. Starokon’ I.V. Issledovanie vliyaniya okruzhayushchej sredy na teplovoe sostoyanie konstruktivnyh ehlementov opornyh blokov morskih stacionarnyh platform. Sovremennye problemy nauki i obrazovaniya, 2014, no. 5.

2017/3
Simulation by means of Petri nets and design of distributed multiuser software suites for gas transportation
Technical sciences

Authors: Dmitry G. LEONOV graduated from Gubkin Russian State University of Oil and Gas in 1992. He is Candidate of Technical Sciences, assistant professor at the Department of Automated Control Systems of Gubkin Russian State University of Oil and Gas (National Research University). Leading developer of the software suite for the gas transportation systems «Vesta». He is author of more than 50 scientific and methodical publications. E-mail: dl@asugubkin.ru
Tatyana M. PAPILINA graduated from Gubkin Russian State University of Oil and Gas in 2012. She is assistant lecturer at the Department of Automated Control Systems of Gubkin Russian State University of Oil and Gas (National Research University). She is specialist in distributed and cloud systems design. E-mail: papilina.tm@asugubkin.ru

Abstract: The article discusses the development and integration of modern distributed software suites in gas transportation dispatching systems. The proposed solution includes transformation of Vesta suite network system into the base of an open integration platform. The platform allows uniting of heterogeneous software suites and standardizes data format and protocols by means of open API. The complexity of tasks necessitates the use of mathematical apparatus providing generalized representation of the whole system. The design of concordant application protocols in distributed computing systems is considered. The matter deals with heterogeneous software interaction and connections of synchronous and asynchronous components of «Vesta» software used in gas transportation industry. The models of the system have been designed by means of colored Petri nets

Index UDK: 51-7:622.691

Keywords: control systems software, automatic dispatch control system, oil and gas transport, colored Petri net

Bibliography:
1. Anisimov N.A., Golenkov E.A., Kharitonov D.I. Kompozitsional’nyy podkhod k razrabotke parallel’nykh i raspredelennykh sistem na osnove setey Petri. Programmirovanie, 2001, no. 6, p. 30.
2. Grigor’ev L.I., Kostogryzov A.I. Aktual’nost’ i osnovy innovatsionnogo puti razvitiya ASDU. Avtomatizatsiya, telemekhanizatsiya i svyaz’ v neftyanoy promyshlennosti, 2016, no. 3, p. 12-20.
3. Kotov V.E. Seti Petri. M.: Nauka, 1984, p. 160.
4. Korotikov S.V., Voevoda A.A. Primenenie setey Petri v razrabotke programmnogo obespecheniya tsentrov distantsionnogo upravleniya i kontrolya. Nauchnyy vestnik Novosibirskogo gosudarstvennogo tekhnicheskogo universiteta, 2007, no. 4, p. 15-32.
5. Leonov D.G. Ob’ektno-orientirovannaya tekhnologiya razrabotki sistem podderzhki prinyatiya dispetcherskikh resheniy v transporte gaza. Avtomatizatsiya, telemekhanizatsiya i svyaz’ v neftyanoy promyshlennosti, 2000, no. 4-5, p. 11-17.
6. Leonov D.G. Primenenie setey Petri k postroeniyu adaptiruemogo raspredelennogo prikladnogo programmnogo obespecheniya. Avtomatizatsiya, telemekhanizatsiya i svyaz’ v neftyanoy promyshlennosti, 2017, no. 1, p. 5-11.
7. Leonov D.G., Vasil’ev A.V. Postroenie mnogourovnevoy sistemy podderzhki prinyatiya dispetcherskikh resheniy, osnovannoe na razvitii raspredelennoy arkhitektury programmno-vychislitel’nogo kompleksa «Vesta». M.: Avtomatizatsiya, telemekhanizatsiya i svyaz’ v neftyanoy promyshlennosti, 2014, no. 6, p. 13-18.
8. Leonov D.G. Papilina T.M. ASDU bez granits. Preodolenie arkhitekturnykh ogranicheniy programmno-vychislitel’nykh kompleksov v avtomatizirovannoy sisteme dispetcherskogo upravleniya. Delovoy zhurnal NEFTEGAZ.RU, 2016, no. 1-2, p. 14-18.
9. Papilina T.M. Platforma razrabotki prikladnykh web-instrumentov dlya dispetcherskogo personala neftegazovoy otrasli. Avtomatizatsiya, telemekhanizatsiya i svyaz’ v neftyanoy promyshlennosti, 2015, no. 11, p. 41-46.
10. Papilina T.M., Leonov D.G., Stepin Yu.P. Modelirovanie i otsenka effektivnosti funktsionirovaniya sistemy oblachnykh vychisleniy v ASDU. Avtomatizatsiya, telemekhanizatsiya i svyaz’ v neftyanoy promyshlennosti, 2016, no. 7, p. 29-33.
11. Polikarpova N.I., Shalyto A.A. Avtomatnoe programmirovanie. SPb.: Piter, 2009, p. 167.
12. Shalyto A.A. Switch-tekhnologiya. Algoritmizatsiya i programmirovanie zadach logi-cheskogo upravleniya. SPb.: Nauka, 1998, p. 628.
13. CPN Tools [Elektronnyy resurs]/ URL: http://cpntools.org/.

2017/3
Improving the performance properties of protective liquids for hot water storage tanks for power plants
Technical sciences

Authors: Igor R. TATUR (b. 1956) graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1979. He is PhD, Associate Professor of the Dept. of Chemistry and Technology of Lubricants and Chemmotology of Gubkin Russia State University of Oil and Gas (National Research University). He is author of more than 120 publications. E-mail: igtatur@yandex.ru
Аleksey V. LEONTYEV (b. 1988) graduated from Gubkin Russian State University of Oil and Gas in 2013. He is post-graduate student of the Department of Chemistry and Technology of Lubricants and Chemmotology of Gubkin Russia State University of Oil and Gas (National Research University). He is Research Fellow in OOO United Research and Development Center (OOO «RN-CIR»). He is author of 10 publications. E-mail: leontievaleksey@gmail.com
Vladimir G. SPIRKIN (b. 1937) graduated from the Military Rocket Forces Academy named after Peter the Great in 1959. He is D.Sc., Professor of of Chemistry and Technology of Lubricants and Chemmotology of Gubkin Russia State University of Oil and Gas (National Research University). He is author more than 350 publications, 10 books and monographs, 35 patents.
E-mail: vgspirkin@mail.ru
Yuliya S. BELOMESTNOVA is a student of the Department of Chemistry and Technology of Lubricants and Chemmotology of Gubkin Russia State University of Oil and Gas (National Research University). She is author of 6 scientific works. E-mail: belomestJ@mail.ru

Abstract: The results of the research of the effect of corrosion inhibitors of various compositions on the protective properties and thermal-oxidative stability of the protective liquid AG-4I (TU 26-02-592-83, Rev. 1-9) are presented. The proportions of corrosion inhibitors of donor, acceptor and insulating action in their composition, which is of synergistic effect, are determined. The effect of corrosion inhibitors on the thermal and oxidative stability of the protective liquid in the presence of oxidation initiator (diiso-butyronitrile) was studied

Index UDK: 665.767; 620.197.7; 691.175.5/8

Keywords: рrotective fluid, corrosion inhibitor, polyisobutylene, hot water storage tanks, protective properties, oxidation initiator, thermooxidation stability, synergistic effect induction period, dynamic viscosity, polymer degradation

Bibliography:
1. Tatur I.R. Zashchita ot korrozii oborudovaniya sistem vodosnabzheniya. Germaniya: LAP LAMBERT Academic Publishing, 2012, р. 75.
2. Uluchshenie antikorrozionnyh svojstv zashchitnyh zhidkostej dlya bakov-akkumulyatorov goryachego vodosnabzheniya ehnergeticheskih predpriyatij/A.V. Leont’ev, I.R. Tatur, D.N. Sheronov, V.G. Spirkin//Trudy RGU nefti i gaza imeni I.M. Gubkina, 2015, no. 4, p. 89-99.
3. Primenenie antiokislitel’nyh prisadok dlya povysheniya termookislitel’noj stabil’nosti zashchitnyh zhidkostej dlya bakov-akkumulyatorov goryachego vodosnabzheniya ehnergeticheskih predpriyatij //I.R. Tatur, D.N. Sheronov, A.V. Leont’ev, V.G. Spirkin//Trudy RGU nefti i gaza imeni I.M. Gubkina, 2016, no. 2 (283), p. 118-130.
4. Bogdanova T.I., SHekhter YU.N. Ingibirovannye neftyanye sostavy dlya zashchity ot korrozii. M.: Himiya, 1984, p. 248.
5. Lebedev V.S. Vliyanie prirodnyh i sinteticheskih ingibitorov na okislenie neftyanyh masel. Avtoref. diss. kand. tekhn. nauk. Moskva, 1986, p. 24.
6. Ocenochnye znacheniya ehkspluatacionnyh pokazatelej germetiziruyushchih zhidkostej dlya bakov-akkumulyatorov goryachego vodosnabzheniya//I.R. Tatur, D.N. Sheronov, A.V. Leont’ev, V.G. Spirkin. Ehnergetik, 2016, no. 4, p. 32-35.

2017/3
Рartial oxidation of n-butanol involving low-temperature singlet oxygen on vanadium and molybdenum oxides
Chemical sciences

Authors: Marina V. VISHNETSKAYA graduated from Lomonosov Moscow State University. She is Doctor of Chemical Sciences, Professor of the Department of Industrial Ecology of Gubkin State University of Oil and Gas (National Research University). She is author of 117 publications in the field of homogeneous and heterogeneous catalysis, fundamental problems of chemical engineering, chemical dynamics, reactivity and chemical kinetics. E-mail: mvvishnetskaya@mail.ru
Olga V. MATROSOVA graduated from Gubkin Russian State University of Oil and Gas in 2010. She is assistant lecturer of the Department of Industrial Ecology at Gubkin Russian State University of Oil and Gas (National Research University). She is expert in the field of environmental protection. She is author of three publications on heterogeneous catalysis. E-mail: mov.86@mail.ru

Abstract: Surface emission of the low-temperature singlet oxygen (1ΔgO2) from the solid solutions of transition metal oxides with the хV2O5×уMoO3 composition was detected and explored. Thereby it was shown that the temperature interval in which low-temperature emission of the singlet oxygen was obsereved, and its amount depend on the composition of solid solutions. The ability to regenerate emission centers of 1ΔgO2 after re-adsorption of molecular oxygen by the catalyst surface was discovered. The relation between the ability of хV2O5×MoO3 to generate 1ΔgO2 and the catalytic activity of this system in the partial oxidation of n-butanol with molecular oxygen was determined and the probable routes of this process were described. It was suggested that the emission 1ΔgO2 is connected with thermal decomposition of peroxide groups.

Index UDK: 541.128

Keywords: singlet oxygen, emission of singlet oxygen, vanadium-molybdenum catalysts, partial oxidation of n-butanol, peroxide groups

Bibliography:
1. Sobolev V.I., Danilevich E.V., Koltunov K.Yu. A role of vanadic forms in the course of selective oxidation of ethanol on V2O5/TiO2 catalysts. Kinetics and a catalysis, 2013, t. 54, no. 6, p. 771–775.
2. Beskopylny A.M., Pai Z.P., Popov Yu.V., Tuchapskaya D.P. Catalytic oxidation of primary aliphatic alcohols hydrogen peroxide. In the world of discoveries, 2010, no. 4–15, p. 20–21.
3. Levitsky M.M., Bilyachenko A.N., Shulpin G.B. Oxidation of  C-H compounds with peroxides catalyzed by polynuclear transition metal complexes. Journal of Organometallic Chemistry, 2017, in press.
4. Patent of the Russian Federation no. 2301790, 2007. Way of oxidation of organic compounds in the presence of hydrogen peroxide (options). E.V. Kuznetsova, L.A. Vostrikova, O.A. Makhotkina, D.V. Kozlov; patent holder Institute of a cata-lysis of G.K. Boreskov of the Siberian office of RAS.
5. Mingzhou Wu, Wangcheng Zhan, Yanglong Guo, Yun Guo, Yunsong Wang, Li Wang, Guanzhong Lu. An effective Mn-Co mixed oxide catalyst for the solvent-free selective oxidation of cyclohexane with molecular oxygen. Applied Catalysis A: General, 2016, vol. 523, p. 97–106.
6. Sobolev V.I., Koltunov K.Yu. Selective gas-phase oxidation of ethanol molecular oxygen on oxidic and gold-bearing catalysts the Catalysis in the chemical and petrochemical industry, 2012, no. 3, p. 20–25.
7. Luis G. Possato, Wellington H. Cassinelli, Camilo I. Meyer, Teresita Garetto, Sandra H. Pulcinelli, Celso V. Santilli, Leandro Martins. Thermal treatments of precursors of molybdenum and vanadium oxides and the formed MoxVyOz phases active in the oxydehydration of glycerol. Applied Catalysis A: General, 2017, vol. 532, p. 1–11.
8. Alessandro Chieregato, Jose M. Lopez Nieto, Fabrizio Cavani. Mixed-oxide catalysts with vanadium as the key element for gas-phase reactions. Coordination Chemistry Reviews, 2015, vol. 301–302, p. 3–23.
9. Sobolev V.I., Koltunov K.Yu. Gas-phase oxidation of alcohols molecular oxygen on the Au/TiO2 catalyst. Role of active oxygen forms. Kinetics and catalysis, 2015, t. 56, no. 3, p. 342–345.
10. Li X., Iglesia E. Selective catalytic oxidation of ethanol to acetic acid on dispersed Mo-V-Nb mixed oxides. Chem. Eur. J., 2007, vol. 13, p. 9324–9330.
11. Patent of the Russian Federation No. 2462307, 2012. Catalyst and way of receiving acetic acid or mix of acetic acid and ethyl acetate. V.I. Sobolev, K.Yu. Koltunov, T.V. Andrushkevich, G.Ya. Popova, V.N. Parmon; patent holder Institute of a catalysis of G.K. Boreskov of the Siberian office of RAS.
12. Iwamoto M., Lunsford J.H. Oxidation of alkanes and alkenes by O2 on MgO. J. Phys. Chem., 1980, vol. 84, p. 3079.
13. Che M., Tench A.J. Characterization and Reactivity of Mononuclear Oxygen Species on Oxide Surfaces. Advances in Catalysis, 1982, vol. 31, p. 77.
14. Che M., Tench A.J. Characterization and Reactivity of Molecular Oxygen Species on Oxide Surfaces. Advances in Catalysis, 1983, vol. 32, p. 1.
15. Sobolev V.I., Koltunov K.Yu. Catalytic Epoxidation of Propylene with CO/O2 over Au/TiO2. Applied Catalysis A., 2014, vol. 476, p. 197.
16. Zavyalov S.A., Butchers I. A., Zavyalov L.M. Thermal formation and emission of singletny oxygen from the surface of pentoxide of vanadium. Zhurnal physical. chemistry, 1984, t. 58, p. 1532–1534.
17. Vishnetskaya M.V., Yemelyanov A.N., Scherbakov N.V., etc. A role of singlet oxygen in transformations of hydrocarbons on zeolites. Zhurnal physical. chemistry, 2004, t. 78, p. 2152.
18. Romanov A.N., Rufov Y.N., Korchak V.N. Thermal Generation of Singlet Oxygen on ZSM-5 Zeolite. Mendeleev Commun, 2000, vol. 10, no. 3, p. 116.
19. Matrosova O.V., Rufov Yu.N., Vishnetskaya M.V. Oxides of transitional metals: low-temperature emission of singlet oxygen. Zhurnal physical. chemistry, 2010, t. 84, no. 12, p. 2387— 2389.
20. Matrosova O.V., Vishnetskaya M.V. Oxidation of sulfites on vanadium-molybdenum oxides. Zhurnal physical. chemistry, 2014, t. 88, no. 1, p. 27–31.
21. Volnov I.I. Peroksokompleks of chrome, molybdenum, tungsten. M.: Science, 1989, 175 p.
22. Abu Haija M., Guimond S., Romanyshyn Y. Low temperature adsorption of oxygen on reduced V2O5(0001) surfaces. Surf. Sci., 2006, vol. 600, p. 1497.
23. Guimond S., Abu Haija M., Kaya S. Vanadium oxide surfaces and supported vanadium oxide nanoparticles. Topics in Catalysis, 2006, vol. 38, no. 1–3, p. 117.
24. Haula E.V., Matrosova O.V., Vishnetskaya M.V., Rufov Yu.N. About the nature of oxygen particles at a low-temperature desorption from vanadium oxides. Zhurnal physical. chemistry, 2011, t. 85, no. 2, p. 394–395.

2017/2
Sedimentation features of Minghuazhen formation Miocene series in Shanxi oilfield of China
Geosciences

Authors: Igor S. GUTMAN graduated from the Moscow Mining Institute in 1956. He has been working as professor of the Department of Production Geology of Gubkin Russian State University (National Research University) of Oil and Gas since 1994, he is also Director of the Institute of Engineering and Scientific Expertise in the Field of Oil and Gas Fields Development (affiliated to the department since 1997) and Center for Computer Modeling of Hydrocarbons (since 2002). He is author of 7 books and more than 150 scientific papers. E-mail: mail@ipne.ru
Zhiqiang GU was born in 1988. Master of engineering and technology. He is Ph.D. student of the Department of Production Geology of Gubkin Russian State University of Oil and Gas (National Research University). E-mail: guzq1988@hotmail.com
Tatyana R. SULTANSHINA Ph.D. student of the Department of Production Geology of Gubkin Russian State University of Oil and Gas (National Research University). Е-mail: sultanshina.tatyana@yandex.ru

Abstract: Based on detailed correlation of well logs in shanxi oil field china and analysis paleosections show that sedimentation of Minghuazhen formation happened under alternate dip of adjacent tectonic blocks and their limiting faults are synsedimentary. Analysis of thickness maps also indicates the presence of block tectonics

Index UDK: 553.98.061.4

Keywords: well logs correlation, block tectonic, synsedimentary faults, Shanxi oil field (China)

Bibliography:
1. Gong Z., Zhang G., Cai D., He S. Late-stage Hydrocarbon Accumulation in the Bozhong Depression of the Bohai Bay Basin as Controlled by Neotectonism//Acta geologica sinica, 2004, vol. 78, no. 3, p. 632–639.
2. Allen M.B., Macdonald D.I.M., Xun Z., Vincent S.J., Brouet-Menzies C. Early Cenozoic two-phase extension and late Cenozoic thermal subsidence and inversion of the Bohai Basin, northern China//Marine and Petroleum Geology, 1997, vol. 14, no. 7/8, p. 951-972.
3. Jiafu Qi, Qiao Yang. Cenozoic structural deformation and dynamic processes of the Bohai Bay basin province, China//Marine and Petroleum Geology, 2010, vol. 27, no. 4, p. 757–771.
4. Zhang Zhen, Bao Zhidong, Tong Hengmao, Wang Yong, Li Haowu. Tectonic evolution and its control over deposition in fault basins: A case study of the Western Sag of the Cenozoic Liaohe Depression, eastern China//Petroleum Science, 2013, no. 10, p. 269–281.
5. Geology of reservoir oil and gas in rift basin, east China/Wang Tao. —Beijing: China petroleum industry press, 1997, 196 p.
6. Gutman I.S., Balaban I.Yu., Staroverov V.M. et al., Metodicheskie rekomendatsii k korrelyatsii razrezov skvazhin [Guidelines to the well log correlation]. Moscow, 2013, 112 p.
7. Gutman I.S., T.R. Sultanshina, S.V. Khalyapin. Structural features of oil deposit in the horizon YuS1 of Gribnoye field. Neftjanoe hozjajstvo. — Oil Industry, 2014, no. 5, >p. 60-64 (in Russian).
8. Shpindler A.A. Evaluation of permeability faults in one of the oilfield of Tomsk region. Problemy geologii i osvoenija nedr: Trudy XVII Mezhdunarodnogo simpoziuma imeni akademika M.A. Usova studentov i molodyh uchjonyh, posvjashhennogo 150-letiju so dnja rozhdenija akademika V.A. Obrucheva i 130-letiju akademika M.A. Usova, osnovatelej Sibirskoj gorno-geologicheskoj shkoly [Problems of Geology and Subsurface Development: Proceedings of the 17th International Scientific Symposium of students, Postgraduates and young Scientists devoted to the 150th Anniversary of Academician V.A. Obruchev and 130th Anniversary of Academician M.A. Usov, Founders of Siberian Mining School]. Tomsk, 2013, pp. 344–355. (in Russian).
9. Sorkhabi R., Suzuki U, Sato D. Structural Evaluation of Petroleum Sealing Capacity of Faults//SPE Asia Pacific Conference on Integrated Modeling for Asset Manager. Yokohama, 2000, p. 230–239.

2017/2
Generation Potential of Oligocene-Miocene Sediments of Cuu Long Basin
Geosciences

Authors: Vu Nam HAI graduated from Gubkin Russian State University of Oil and Gas in 2015. He is an assistant of the Department of Prospecting and Exploration of Oil and Gas of Gubkin Russian State University of Oil and Gas (National Research University). Scientific interests are in the areas of 3D modeling of the hydrocarbon systems and the oil and gas potential on the continental shelf of Vietnam. He has published 3 works.
E-mail: sphere1707@yandex.ru

Abstract: The article is devoted to the research of the generation potential of Oligocene—Miocene sediments of the Cuu Long basin on the basis of the results of digital modelling of the generation-accumulation system. The main oil-and-gas source rocks of the basin have been studied. These are represented by fine-grained sediments of the lake-marsh facies of Oligocene age and contain rich amount of organic matter as well as type I and II kerogen. Currently, the source rocks reach maturity threshold at the depth of around 2700-2900 m, the depth of the oil window ranges from 3100 to 3400 m, the dry gas window occurs at deeper than 5500 m. According to the results of the pyrolysis analysis of the core samples and sludge samples, organic matter of Lower Miocene source rocks has not yet reached maturity to generate hydrocarbons, except for the submerged parts of the central depression where organic matter has partially reached such maturity thresholds. 3D modeling of the generation-accumulation hydrocarbon systems helped to build distribution maps of vitrinite reflectance values (Ro %) in the Cuu Long basin. On the basis of the digital model, created with a PetroMod petroleum systems modeling software, the zone of distribution of hydrocarbon deposits is forecasted

Index UDK: 550.8

Keywords: prospect, exploration, reserves, hydrocarbons, reservoir, oil, gas, kerogen, digital model, facies, hydrocarbon system, Cuu Long basin

Bibliography:
1. Kerimov V.Ju., Mustaev R.N., Senin B.V., Lavrenova E.A. Zadachi bassejnovogo modelirovanija na raznyh jetapah geologorazvedochnyh rabot. Neftjanoe hozjajstvo, 2015, no. 4, p. 26-29.
2. Leonova E.A. Geologicheskoe stroenie i neftegazonosnost’ Shonghongskogo progiba (severnyj shel’f V’etnama). Trudy Rossijskogo gosudarstvennogo universiteta nefti i gaza imeni I.M. Gubkina, 2016, no. 2, p. 16.
3. Shnip O.A. Sostav i neftegazonosnost’ phundamenta shel’fa severnogo i central’nogo V’etnama. Trudy Rossijskogo gosudarstvennogo universiteta nefti i gaza imeni I.M.Gubkina, 2012, no. 1, 53 p.
4. Geologija i neftegazonosnost’ phundamenta Zonkskogo shel’fa. E.G. Aresev, V.P. Gavrilov, Chan Le Dong, Nguyen Dao, Ngo Thuong San, O.A. Shnip i dr. M.: Izdatel’stvo «Neft’ i gas», 1997, p. 56-65.
5. Nguyen Van Duc, Ivanov A.N., Pham Xuan Son, Vu Van Khuong. Otchet «Izuchenie uclovii phormirovanija zalejei uglevodorodov v Cuulongckom bacceine dlja vyjavlenija geologicheskih zakonomernoctei ih razmeshhenija», tema no. NIP-I.4, NIPI morneftegas, SP «Vietsovpetrol», 2013, p. 40-45.

2017/2
Modelling of geo-fluid pressures within the Sakhalin shelf
Geosciences

Authors: Rustam N. MUSTAEV graduated from Orenburg State University in 2010. He is Candidate of Geological and Mineralogical Sciences, assistant professor of the Department of Theoretical Fundamentals of Prospecting and Exploration of Oil and Gas of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the Black Sea-Caspian megabasin. He is author of 52 scientific publications, two monographs and two textbooks. E-mail: r.mustaev@mail.ru
Alexander V. OSIPOV graduated from Gubkin Russian State University of Oil and Gas in 2010. He is Candidate of Geological and Mineralogical Sciences, assistant professor of the Department of Theoretical Fundamentals of Prospecting and Exploration of Oil and Gas of Gubkin Russian State University of Oil and Gas (National Research University). He is author of more than 50 scientific publications, including one monograph and a textbook for high schools. E-mail: osipov.a@gubkin.ru
Vagif Yu. KERIMOV was born in 1949. He graduated from Azizbekov Azebaijan Institute of Oil and Petrochemistry. He is Doctor of Geological and Mineralogical Sciences, professor, Head of the Department of Theoretical Fundamentals of Prospecting and Exploration of Oil and Gas of Gubkin Russian State University of Oil and Gas (National Research University). He has published over 200 works. E-mail: vagif.kerimov@mail.ru
Alexander V. BONDAREV is Candidate of Geological and Mineralogical Sciences, assistant professor of the Department of Theoretical Fundamentals of Prospecting and Exploration of Oil and Gas of Gubkin Russian State University of Oil and Gas (National Research University). He is author of more than 30 scientific publications. E-mail: jcomtess@yandex.ru

Abstract: Based on the results of the simulation with respect for the assessment of the changes in the compaction of rocks and their filtration-capacitance properties and density the zones of abnormal pore pressures are identified in the section of the Prisakhalin shelf. The results of the log-derived pore pressure estimation by the equivalent depth method are presented. The results of modeling are compared with the data obtained by various methods and direct borehole measurements. The influence of neotectonic processes on the distribution of pressures is estimated. The effect of unloading zones on the process of formation of abnormal pore pressures zones is estimated. The difference in the distribution of pore pressures was established within the Kirinsky license area, in the South Ayash structure and in the Piltun-Astokhskoye field

Index UDK: 550.8:004.9

Keywords: abnormal pore pressure, gas, geo-fluid pressure, modeling, oil, den- sity, Prisakhalin shelf, hydrocarbons, compaction

Bibliography:
1. Aleksandrov B.L., Shilov G.Ya., Kerimov V.Yu.O., Belyaev S.V., Skripka A.A. Osobennosti kolichestvennoy otsenki anomal’no vysokikh porovykh davleniy po dannym GIS v slozhnykh geolo- gicheskikh usloviyakh Messoyakhskoy gruppy mestorozhdeniy uglevodorodov. Karotazhnik, 2010, no. 5, p. 41-51.
2. Bogoyavlenskiy V.I., Kerimov V.Yu., Ol’khovskaya O.O., Mustaev R.N. Povyshenie effektivnosti i bezopasnosti poiskov, razvedki i razrabotki mestorozhdeniy nefti i gaza na akvatorii Okhot-skogo moray. Territoriya Neftegaz, 2016, no. 10, p. 24-32.
3. Guliev I.S., Kerimov V.Yu., Mustaev R.N. Fundamental’nye problemy neftegazonosnosti Yuzhno-Kaspiyskogo basseyna. Doklady Akademii nauk RF, 201, t. 471, no. 1, p. 62-65.
4. Kerimov V.Yu., Bondarev A.V., Sizikov E.A., Sinyavskaya O.S., Makarova A.Yu. Usloviya formirovaniya i evolyutsii uglevodorodnykh sistem na Prisakhalinskom shel’fe Okhotskogo moray. Neftyanoe khozyaystvo, 2015, no. 8, p. 22-27.
5. Kerimov V.Yu., Gorbunov A.A., Lavrenova E.A., Osipov A.V. Modeli uglevodorodnykh sistem zony sochleneniya Russkoy platformy i Urala. Litologiya i poleznye iskopaemye, 2015, no. 5, p. 445-458.
6. Kerimov V.Yu., Guliev I.S., Guseynov D.A., Lavrenova E.A., Mustaev R.N., Osipov A.V., Serikova U.S. Prognozirovanie neftegazonosnosti v regionakh so slozhnym geologicheskim stroeniem. M.: OOO «Izdatel’skiy dom Nedra», 2015, 404 p.
7. Kerimov V.Yu., Lavrenova E.A., Sinyavskaya O.S., Sizikov E.A. Otsenka uglevodorodnogo potentsiala generatsionno-akkumulyatsionnykh uglevodorodnykh sistem Okhotskogo moray. Trudy Rossiyskogo gosudarstvennogo universiteta nefti i gaza im. I.M. Gubkina, 2015, no. 3, p. 18-30.
8. Kerimov V.Yu., Rachinskiy M.Z. Geoflyuidodinamicheskaya kontseptsiya akkumu- lyatsii uglevodorodov v prirodnykh rezervuarakh. Doklady Akademii nauk RF, 2016, t. 471, no. 2, p. 187–190.
9. Osipov A.V., Zaytsev V.A., Ryabukhina S.G., Bondarev A.V. Geomekhanicheskoe modelirovanie kollektorskikh svoystv Kirinskogo litsenzionnogo uchastka (Prisakhalinskiy shel’f). 18-aya nauchno-prakticheskaya konferentsiya po voprosam geologorazvedki i razrabotki mestorozhdeniy nefti i gaza «Geomodel’-2016», Gelendzhik, 2016.
10. Osipov A.V., Zaytsev V.A., Ryabukhina S.G., Sizikov E.A. Otsenka vtorichnykh fil’tra-tsionnykh parametrov kollektorov v rezul’tate geomekhanicheskogo modelirovaniya (Prisakhalinskiy shel’f). 18-aya nauchno-prakticheskaya konferentsiya po voprosam geologorazvedki i razrabotki mestorozhdeniy nefti i gaza «Geomodel’-2016», Gelendzhik, 2016.
11. Shilov G.Ya., Vasilenko E.I., Osipov A.V. Issledovanie flyuidodinamicheskikh faktorov pri poiskakh skopleniy glubinnykh uglevodorodov v zemnoy kore. Neft’, gaz i biznes, 2015, no. 8, p. 25-30.
12. Rachinsky M.Z., Kerimov V.Yu. Fluid dynamics of oil and gas reservoirs. Scientific Editor Gorfunkel M.V. Scrivener Publishing, USA, 2015, 622 p.

2017/2
Mineralogical features of Osinskiy horizon carbonate reservoir rocks of Nepsko-Botuoba anteclise
Geosciences

Authors: Andrey S. KUZNETSOV is post-graduate student and senior engineer of the Department of Lithology of Gubkin Russian State University of Oil and Gas (National Research University). E-mail: andrey.kuznecov.91@mail.ru
Irina A. KITAEVA is Assistant Lecturer of the Department of Lithology of Gubkin Russian State University of Oil and Gas (National Research University). E-mail: irina_kitaeva@bk.ru

Abstract: The main carbonate deposits rock types of Osinskiy horizon of Nepsko-Botuo- ba anteclise were distinguished and characterized. The detailed mineralogical analysis of distinguished lithotypes, which was perfomed by the methods of x-ray diffractometry and microprobe analysis, detected a wide spectrum of authigenic minerals, such as halite, anhydrite, ankerite, graphite, cuboargyrite etc., in limestone and dolomite rocks. The ankerite formation mechanism was validated. The absence of direct correlation between potassium anomalies in Osinskiy horizon basement and presence of clay minerals were determined. The minerology of intervals with increased radioactivity values was characte-rized

Index UDK: 551.7.022

Keywords: carbonate rocks, minerology, lower Cambrian, Osinskiy horizon, Nepsko-Botuoba Anteclise, Siberian platform

Bibliography:
1. Dmitrievsky A.N., Kuznetsov V.G., Iluhin L.N., Postnikova O.V. and colleagues Structure and conditions of formation of Osinskiy horizon of the south part of Siberian platform complimented by it’s oil-and-gas content. Prediction of oil and gas occurrence of East Siberia. MINHiGP, 1990, p. 23-28.
2. Eskin A.A. Morphological and genetic types of the void space structures of carbonate rocks and factors of their formation (evidence from the eastern side of Melekesskaya depression and the western side of Yuzhno-Tatarsky arch). Author’s abstract candidate of geological and mineralogical sciences. Kazan, 2014, p. 21.
3. Konovalceva E.S. Secondary processes in reservoir rocks of productive sediments of Yaractinski deposit. Neftegazovaya Geologiya. Teoriya I Praktika, 2010, no. 5, p. 6-7. http:// www.ngtp.ru/rub/2/18_2010.pdf
4. Neruchev S.G. Periods of radioactivity on the Earth surface and their influence on the orga- nic world revolution. Neftegazovaya Geologiya. Teoriya i praktika, 2007, no. 2, p. 3-8. http:// www.ngtp.ru/rub/10/032.pdf