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Hilden, Germany+49 (1577) 958-68-49

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:Tayfun Babadagli / tayfun@ualberta.ca .. / tshuster@mail.ru .. / zavidey@vei.ru .. / manukov@cge.ru .. / gngogonenkov@cge.ru .. / kemalov@mail.ru .. / kemalov@mail.ru .. / bekten_1954@mail.ru .. / redactor@anrb.ru .. / M.Pesin@mail.ru .. / lab105@rambler.ru .. / elena@ek7740.spb.edu .. / ishmatov@mail.ru

: 420108, . , . , 25 : +7 (843) 231-05-46 04-15/03-1

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5

6ISSUE: 2 (41) april 2015

GENERAL OFFICE:N.Chelny, Republic of Tatarstan, Russia3/14 Mira avenue, Suite 145 +7 (8552) 38-51-26, 38-49-47

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EDITIORIAL BOARD:Tayfun Babadagli / tayfun@ualberta.caVladimir Shuster / tshuster@mail.ruVictor Zavidey / zavidey@vei.ruVictor Manukov / manukov@cge.ruGeorgiy Gogonenkov / gngogonenkov@cge.ruAlim Kemalov / kemalov@mail.ruRuslan Kemalov / kemalov@mail.ruNesipkhan Bektenov / bekten_1954@mail.ruElshad Telyashev / redactor@anrb.ruMikhail Pesin / M.Pesin@mail.ruOleg Lukianov / lab105@rambler.ruElena Kotelnikova / elena@ek7740.spb.eduZakir Ishmatov / ishmatov@mail.ru

PRINTED:Logos typography Kazan +7 (843) 231-05-46

ISSUE DATE:13.04.2015

CIRCULATION:10 000 copies

Geophysics .................................................................................................................................10

Alexey A. Nezhdanov, Valery V. Ogibenin, Sergey A. Gorbunov Method of Cenomanian gas deposits mapping on the example of Krusenstern field ..................10

Oil production ............................................................................................................................16

Sergei V. Maklakov, Mikhail A. Moiseev The impact of core compressibility on the displacement efficiency ............................................16

Vladimir R. Khachaturov, Alexander N. Solomatin, Alexander K. Skiba Planning the development of gas fields' group taking into account uncertainty of basic data ........................................................................................... 20

Vladimir V.Shaydakov, Artem L. Sukhonosov, Alla R. Lyudvinitskaya, Riad D. Dzhafarov Gas withdrawal in the arrangement ESCP with packer ........................................................... 24

Aleksandr E. Vorob'ev. Basic principles for effective use of industrial nanotechnology during aquatic gas hydrates production ...................................... 28

Igor P. Novikov, Alexander S. Primachenko, Marina V. Lapshin Experimental works by polymeric composition MPS REIS-H to behind casing leaks response at Ivinsky field ..................................................................... 32

Valves ........................................................................................................................................ 38

Ilgiz R. Chinjaev, Aleksandr V. Fominykh, Egor A. Poshicalov, Stanislav A. Sukhov The throughput ability of shutoff and control valves ................................................................ 38

Corrosion ................................................................................................................................... 46

Anatoliy N. Monakhov, Aleksandr K. Kuznetsov, Maria A. Monakhova Experience of using corrosion sensors in corrosion monitoring systems ................................... 46

Valeriy I. Trusov, Renata S. Krymskaya, Lora P. Danilovskaya, Tatiana M. Kuzinova Corrosion inhibitor for the preservation internal surfaces ........................................................ 50

Lubov E. Lenchenkova, Arkadiy R. Epsteyn, Askar R. Mavzyutov, Artur I. Akhetov Device of electrochemical anticorrosive protection for downhole pumping unit ........................ 52

Ecology ..................................................................................................................................... 59

Ilmer Yu. Khasanov, Boris S. Zhirnov, Ural R.Ilyasov, Vladimir I.Rogozin Efficient utilization technology of petroleum gas at oil separation last stage ............................. 59

Vladislav O. Dryakhlov, Ildar G. Shaikhiev, Ildar S. Abdullin, Alina V. Fedotova Water-oil emulsion treatment by combined method using membrane and sorption technologies ...................................................................................................... 62

Yuriy I. Tokarev, Ruslan V. Andreev, Konstantin M. Dligach. Oil slime processing ....................... 66

Alim F. Kemalov, Ruslan A. Kemalov Complex inhibition technology of bituminous insulating materials for the purpose of reduction of technogenic influence on ecology ............................................ 68

Alim F. Kemalov, Ruslan A. Kemalov. Utilization of fulfilled catalysts to reduce ecological hazards during isolation materials production ..........................................71

Activities ....................................................................................................................................74

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AbstractToday on Cenomanian gas field of West Siberia northen regions and circumfluent water area are presented main Russian dry gas stocks and it provides commercial production. For this reason mapping Cenomanian deposits in detail as at natural state as in different production stages still is an important issue.

Materials and methodsDuring the work were used data of common

depth point method (CDP), 2D and 3D seismic survey.

ResultsObtained method of analysis of time slot is used to forecast of effectiveness of gas thickness and structure of net sand coefficient in Cenomanian gas deposits of Krusenstern field. Expected mistake of seismic forecast of net sand coefficient is not more than margin of error of reservoir quality discrimination by GIS system.

ConclusionsThat method could be use for geological exploration, estimation of hydrocarbon reserves, design of production and gas stocks operation monitoring. It is also a solution for problem of forecast precision which based on seismic survey data in standard processing mode.

Keywordsseismic survey, CDP method, West Siberian field, Cenomanian gas field, oil and gas thickness

Method of Cenomanian gas deposits mapping on the example of Krusenstern fieldAuthors:Alexey A. Nezhdanov doctor of geology and mineralogy, deputy director of research1; a.nezhdanov@ggr.gazprom.ruValery V. Ogibenin candidate of geology and mineralogy, director1; v.ogibenin@ggr.gazprom.ruSergey A. Gorbunov deputy director of seismic survey interpretation department1; s.gorbunov@ggr.gazprom.ru 1"Gazprom Geologorazvedka" LLC, Tyumen, Russian Federation

UDC 550.3

ENGLISH GEOPHySICS

References1. Levyant. V.B, Ampilov Yu.P. Glogovskiy

V.M. and others. Metodicheskie rekomendatsii po ispol'zovaniyu dannykh

seysmorazvedki (2D, 3D) dlya podscheta zapasov nefti i gaza [Methodical recommendations to use the seismic

survey data (2D, 3D) for estimation of oil and gas reserves]. Moscow: Tsentral'naya geofizicheskaya ekspeditsiya, 2006, 40 p.

16 622.276

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AbstractFor estimation of the displacement efficiency the results of the laboratory studies of core have been used as the background data. The estimation has been carried out with the use of petrophysical parameters, such as residual water saturation and the pore volume.

Materials and methodsOST 39-195-86 Oil. The method of estimating the water-oil displacement efficiency under the laboratory conditions.

ResultsIn this study the estimation of the displacement efficiency has been carried out with account for the impact that the core samples compressibility has on such parameters as residual water saturation and the pore volume. The laboratory studies have shown the compressibility leads to the change in pore volume previously occupied by the residual water saturation.

ConclusionsWith account for the impact that the coresamples compressibility has on the displacement efficiency, the latter has grown within the range of 15.66%48.64%.

Keywordsdisplacement efficiency, kerosene oil, core, compressibility

The impact of core compressibility on the displacement efficiencyAuthors:Sergei V. Maklakov engineer of the flowmetry studies laboratory of the petrophysics department1; Maklakovsv@rambler.ruMikhail A. Moiseev head of the flowmetry studies laboratory of the petrophysics department1; Moiseevma1983@mail.ru

1LLC "TyumenNIIgiprogas", Tyumen, Russian Federation

UDC 622.276

ENGLISH OIL PRODUCTION

References1. Bannyy V.A., Khod'kov E.N. Vliyanie

davleniya gidroobzhima kernoderzhatelya na fil'tratsionnye svoystva gornoy porody [The impact of the hydroswaging pressure

of the core holder on the flow properties of rock]. Tambov University Reports, 2013, Vol.18, issue 42, pp. 16931694.

2. OST 39-195-86 Oil. Metod opredeleniya koeffitsienta vytesneniya nefti vodoi v

laboratornykh usloviyakh [The method of estimating the water-oil displacement efficiency under the laboratory conditions]. Moscow: Minnefteprom, 1986.

. 5

. 4

// . 2013. . 18, 42, . 16931694.

2. 39-195-86 . . .: , 1986.

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6. .., .. // . VII . . MLSD'2013. .: , 2013. . 2. . 6871.

7. .., .., .. // . VII

23

AbstractIt is proved a choice of fuzzy sets for strategy generation of development of gas fields' group taking into account uncertainty of basic data. According to approximated and combinatory method it is offered an approach to implementation the fuzzy extension of simulation and optimization determined problems to development of gas fields' group. Various tasks are considered that arise in the presence of uncertainty in an assessment of gas reserves of various categories.It were presented solutions on effective implementation of System of simulation and optimization of the gas production taking into account uncertainty of basic data.

Materials and methodsFuzzy mathematics, interval mathematics, simulation models, methods of discrete optimization, computer-aided systems of planning.

ResultsUsing of fuzzy sets for the accounting of uncertainty basic data in particular gas reserves of various categories is considered during planning the gas fields' group development.

ConclusionsFuzzy sets can be successfully applied to forming a strategy of gas fields' group

development taking into account uncertainty of basic data, including the various categories gas reserves. For this purpose it is expedient to use a fuzzy enhancing of the determined problems of simulation and optimization the development of gas fields' group in conditions when objective function and restrictions of optimizing tasks can't be defined analytically. Fuzzy extension can be effectively realized in System of simulation and optimization of the gas production.

Keywordsgroup of gas fields, production planning, simulation and optimization, data uncertainty, fuzzy sets, categories of gas reserves

Planning the development of gas fields' group taking into account uncertainty of basic dataAuthors:Vladimir R. Khachaturov ph.d., professor, head of department1, academician2, academician3Alexander N. Solomatin ph.d., leading researcher1; solan116@mtu-net.ruAlexander K. Skiba ph.d., senior researcher1

1Dorodnicyn Computing Centre of RAS, Moscow, Russian Federation2Russian academy of astronautics, Moscow, Russian Federation3Russian academy of natural sciences, Moscow, Russian Federation

UDC 65.011.56

ENGLISH GAS PRODUCTION

References1. Khachaturov V.R. Matematicheskie metody

regional'nogo programmirovaniya [Mathematical methods of regional programming]. Moscow: Nauka, 1989, 304 p.

2. Khachaturov V.R. Approksimatsionno-kombinatornyy metod dekompozitsii i kompozitsii sistem i konechnye topologicheskie prostranstva, reshetki, optimizatsiya [Approximating and combinatory method of decomposition and composition systems and finite topological spaces, lattices, optimization]. Zhurnal vychislitel'noy matematiki i matematicheskoy fiziki, 1985, Vol. 25, issue 12, pp. 17771794.

3. Margulov R.D., Khachaturov V.R., Fedoseev A.V. Sistemnyy analiz v perspektivnom planirovanii dobychi gaza [The system analysis in advance planning of gas production]. Moscow: Nedra, 1992, 287 p.

4. Skiba A.K., Solomatin A.N. Modelirovanie i optimizatsiya strategiy razrabotki gruppy gazovykh mestorozhdeniy [Simulation and optimization of the gas fields' group development strategy]. Moscow: CC RAS, 2012, 40 p.

5. Solomatin A.N. Nekotorye optimizatsionnye zadachi dlya gruppy gazovykh

mestorozhdeniy [Some optimization tasks for the gas fields' group]. Moscow: CC RAS, 2009, 44 p.

6. Solomatin A.N., Skiba A.K. Modelirovanie i optimizatsiya razrabotki gruppy gazovykh mestorozhdeniy s uchetom neopredelennosti iskhodnykh dannykh [Modeling and optimization of development the gas fields' group taking into account uncertainty of basic data]. Proc. VII Int. Conf. MLSD'2013. Moscow: ICS RAS, 2013, Vol. 2, pp. 6871.

7. Skiba A.K., Solomatin A.N., Bobylev V.N. Nechetkie mnozhestva pri opisanii kategoriy zapasov gaza [Fuzzy sets at the description of gas stocks categories]. Proc. VII Int. Conf. MLSD'2013. oscow: ICS RAS, 2013, Vol. 1, pp. 213216.

8. Mirzadzhanzade A.Kh., Kuznetsov O.L., Basniev K.S., Aliev Z.S. Osnovy tekhnologii dobychi gaza [Bases of gas production technology]. Moscow: Nedra, 2003, 880 p.

9. Yudin D.B. Matematicheskie metody upravleniya v usloviyakh nepolnoy informatsii. Zadachi i metody stokhasticheskogo programmirovaniya [Mathematical methods of management in the conditions of incomplete information. Tasks and methods of stochastic programming]. 3rd ed.

oscow: URSS, 2010, 399 p. 10. Altunin A.E., Semukhin M.V. Modeli i

algoritmy prinyatiya resheniy v nechetkikh usloviyakh [Models and algorithms of decision-making in fuzzy conditions]. Tyumen': TSU, 2000, 352 p.

11. Nedosekin A.O. Nechetkie mnozhestva i finansovyy menedzhment [Fuzzy sets and financial management]. oscow: Audit i finansovyy analiz, 2003, 184 p.

12. Zholen L., Kifer M., Didri O., Val'ter E. Prikladnoy interval'nyy analiz [Applied interval analysis]. 2nd ed. oscow: RKhD, 2007, 468 p.

13. Lyu B. Teoriya i praktika neopredelennogo programmirovaniya [Theory and practice of uncertain programming]. oscow: BINOM, 2005, 416 p.

14. Konysheva L.K., Nazarov D.M. Osnovy teorii nechetkikh mnozhestv [Bases of the theory of fuzzy sets]. Saint Petersburg: Piter, 2011, 192 p.

15. Klassifikatsiya zapasov mestorozhdeniy, perspektivnykh i prognoznykh nefti i goryuchikh gazov [Classification of fields reserves, perspective and expected resources of oil and fuel gases]. The State Commission on Mineral Reserves of the Council of Ministers of the USSR, Moscow, 1983.

. . MLSD'2013. .: , 2013. .1. . 213-216.

8. .., .., .., .. . .: , 2003. 880 .

9. .. . . 3- . .: URSS, 2010. 399 .

10. .., .. . : , 2000. 352 .

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12. ., ., ., . . 2- . .: , 2007. 468 .

13. .

. .: , 2005. 416 .

14. .., .. . .: , 2011. 192 .

15. , . . ., 1983.

24 622.276

.. , 1 2

v1v2sh50@yandex.ru

.. - , 3

suhonos@mail.ru

.. , 1

Ljudvinickaja@yandex.ru

.. 4

nkmz@nkmz.ru

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1. .., ..,

.. . -// . 2007. 3. . 5458.

2. . : http://www.novomet.ru/science_files/512810572005.pdf

3. . : - // . 2011. 11. . 7073.

4. .. , .., .. - - // . . . 2012. 12. . 6467.

5. .. - . // . 2005. 1. . 94104.

6. .. .. . // . 2012. 9.

7. .., .., .., .., .. - // . . . 2011. 9.

8. .., .., .., .., .. - . // . 2011. 9.

9. .. - , , // . . . 2012. 12. .5459.

. 2 . 3

27

AbstractLeakage of casing column is a cause of fast water increase in products of oil-wells. The article discussed layout plan of ESCP with packer, in particular a gas withdrawal through capillary pipeline. It is described the designs packer with Inkompneft capillary pipeline. Experience of arranges applications is given. An approach to hydrates deposition in the capillary pipeline assessment is covered.

Materials and methodsRunge-Kutta method. Method for the

numerical solution of steady-state heat equation the Stefan problem.

ResultsThe article considered a possibility of hydrates deposition in the small bore pipeline. Hydrates increase rate and depth of possible deposition are determined.

ConclusionsIt was designed a mathematical model to forecast the possibility of commencement and rate of growth of the hydrate layer formation and depending on the bottomhole pressure,

temperature gradient of bore hole and gas composition. That, in its turn, allows making a prognosis of the time of uninterrupted performance of the gas withdrawal system. In case of necessity to set the periodicity of the armored polymer pipeline purging to destruct and remove the hydrate layer to save the flow capacity.

Keywordsleakage of casing column, packer, gas withdrawal, capillary pipeline, deep-well pump, hydrates deposition, Stefan condition, heat flow rate

Gas withdrawal in the arrangement ESCP with packer

Authors:Vladimir V.Shaydakov ph.d, professor1, director2; v1v2sh50@yandex.ruArtem L. Sukhonosov ph.d., associate professor3; suhonos@mail.ru Alla R. Lyudvinitskaya ph.d, associate professor1; Ljudvinickaja@yandex.ruRiad D. Dzhafarov general director4; nkmz@nkmz.ru

1Ufa State Petroleum Technical University, Ufa, Russian Federation2Engineering company Inkomp-neft LLC, Ufa, Russian Federation3Ufa State Aviation Technical University, Ufa, Russian Federation4Trade House Neftekamsk machine building plant, Neftekamsk, Russian Federation

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References1. Dengaev A.V., Drozdov A.N.,

Verbitskiy V.S., and others. Problemy nasosnoy dobychi nefti iz skvazhin s negermetichnymi ekspluatatsionnymi kolonnami v OOO "RN-YuGANSKNEFTEGAZ" [Problems of pumping extraction of oil from the wells with the unsealed production strings in RN-YUGANSKNEFTEGAZ LLC]. Territoriya neftegaz, 2007, issue 3, pp. 5458.

2. Oborudovanie dlya dobychi nefti s vysokim soderzhaniem svobodnogo gaza i opyt ego ekspluatatsii [Equipment for production of oil with high content of non-associated gas and experience of the equipment maintenance]. Access mode: http://www.novomet.ru/science_files/512810572005.pdf

3. Afanasyev. A. UETsN s pakerom: opyt TNK-BP [ESCP with packer: experience of TNK-BP]. Neftegazovaja vertikal, 2011, issue 11, pp. 7073.

4. Yagutin R.A., Sakhan A.V., Kostyuchenko S.A. Opyt remontno-izolyatsionnykh rabot v slozhnykh geologicheskikh usloviyakh OOO RN-Purnetegaz [Experience of repair and insulation works in the complicated geological

conditions RN-Purnetegaz LLC]. Neft. Gaz.Novatsii, 2012, issue 12, pp. 6467.

5. Spiridonov E.K. Konstruktsii zhidkostno-gazostruynykh nasosov. Sostoyanie i perspektivy [Gas-jet pumps design. Condition and perspectives] Vestnik YuUrGU, 2005, issue 1, pp. 94104.

6. Chursin K.V., Nikolaev O.S. Ogranichenie vodopritoka metodom ustanovki pakernykh sistem s kabel'nym vvodom. Energosberegayushchie pakernye tekhnologii [Water suppression by method of packer system installation with a cable input. Energy saving technologies] Engineering practice, 2012, issue 9.

7. Aminev M.Kh., Shamilov F.T., Shaydakov V.V., Shaydakov E.V., Afanasyev A.V. Opytno-promyshlennye ispytaniya pakernoy komponovki s tekhnologiey otvoda gaza [Experimental industrial testing of the packer arrangement with gas withdrawal technology]. Neft. Gaz. Novatsii, 2011, issue 9.

8. Aminev M.Kh., Shamilov F.T., Shaydakov V.V., Shaydakov E.V., Afanasyev A.V. Opytno-promyshlennye ispytaniya pakernoy komponovki s tekhnologiey otvoda gaza [Experimental industrial testing of the packer arrangement with

gas withdrawal technology]. Neft Rossii, 2011, issue 9.

9. Kireev A.M. Pakerno-yakornoe oborudovanie i tekhnologii dlya stroitel'stva, osvoeniya, ekspluatatsii i remonta skvazhin [Packer and anchor equipment and technologies for wells construction, development, maintenance and repair]. Neft. Gaz. Novatsii, 2012, issue 12, pp. 5459.

10. Bondarev E.A., Gabysheva L.N., Kanibolotsky M.A. Modelirovanie obrazovaniya gidratov pri dvizhenii gaza v trubakh [Hydrates development stimulation at gas flow in the pipes] Izv.AN USSR. Mechanics of liquid and gas, 1982, issue 5, pp. 105112.

11. Khayrullin M.Kh., Shamsiev M.N., Morozov P.E., Tulupov L.A. Modelirovanie gidratoobrazovaniya v stvole vertikal'noy gazovoy skvazhiny [Hydrates development stimulation in the gas vertical well]. Vychisl.tekhnologii, 2008, Vol. 13, issue 5, pp. 8894.

12. Argunova K.K., Bondarev E.A., Rozhin I.I. Matematicheskie modeli obrazovaniya gidratov v gazovykh skvazhinakh [Mathematical models of hydrates development in the gas wells]. Kriosfera Zemli, 2011, Vol. XV, issue 2, pp. 6569.

10. .., .., .. // . . . 1982. 5. . 105112.

11. .., .., .., .. - // . -. 2008. . 13. 5. . 8894.

12. .., .., .. // . 2011. . XV. 2. . 6569.

28 622.276

.. 1 fogel_al@mail.ru

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:1. .., ..,

.., .. // . 2006. 7.

2. RU 2213692. - , , .

3. .., .. . .: , 2009. 106 .

4. .., .., .., .. : . : , 2013. 403 .

5. .., ..

// . 1998. 3. . 5564.

6. . : http://youege.com/vysokie-texnologii/ezhi-i-nanostruktury ( 19.02.2015).

7. ., .., .. . . , 2003. . 393. 6. . 822826.

8. .. : , , // . 2003. . 47. 3. . 7079.

9. .. . , 2009.10. .

. : http://www.microbot.ru/modules/Static_Docs/data/2_Nanotechnology/2_Basic_Technologies/_Actuators/031202_svidinenko_nanoactuator_rewiev/index.htm ( 19.02.2015)

11. . : http://persona.rin.ru/news/63902/f/uchenye-prodemonstrirovali-princip-raboty-molekuljarnyh-nanomotorov ( 19.02.2015)

12. . . , . , 2008.

13. .. . . -. .. . .-: , 2010. 692 .

AbstractThe article describes the various process of gas hydrates generation and corresponding to it industrial methane production technology of these. Presents a variety of types of nanoparticles which make effectually the development of gas hydrate deposits.

Materials and methodsAnalytical methods.

ResultsThe results of the experiments show that the most effective implementation of the gas hydrate deposits development is nanotechnology.

ConclusionsDifferent types of gas hydrate deposits (porphyritic, massive, pellets, dykes, veinlets, etc.), as well as their mixing

with the formation of sludge and silt particles will determine the possible quantitative parameters and the basic modes of industrial technologies in their development.

Keywordsgas hydrates, the formation mechanism, the principles of fracture, nanotechnology, nanoparticles

Basic principles for effective use of industrial nanotechnology during aquatic gas hydrates productionAuthor:Aleksandr E. Vorob'ev head of department1; fogel_al@mail.ru

1Department of petroleum geology, mining and oil and gas business of Peoples' Friendship University of Russia, Moscow, Russian Federation

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. 6 () [7]: ; , ; D ; -;

F ( ); G ; H, I, J

31

References1. Basniev K.S., Kul'chitskiy V.V.,

Shchebetov A.V., Nifantov A.V. Sposoby razrabotki gazogidratnykh mestorozhdeniy [Ways to develop gas hydrate deposits]. Gas industry, 2006, issue 7.

2. Patent RU 2213692. Vodnyy molekulyarno-kolloidnyy rastvor, po men'shey mere, odnogo gidratirovannogo fullerene [Water molecular colloidal solution of at least one hydrated fullerene].

3. Vorob'ev A.E., Malyukov V.P. Nanoyavleniya i nanotekhnologii pri razrabotke neftyanykh i gazovykh mestorozhdeniy [Nanophenomena and nanotechnology in the development of oil and gas fields]. Moscow: PFUR, 2009, 106 p.

4. Vorob'ev A.E., Moldabaeva G.Zh., Oryngozhin E.S., Chekushina E.V. Akval'nye zalezhi gazogidratov: resursy i innovatsionnye tekhnologii osvoeniya [Aquatic deposits of gas hydrates: resources and innovative technology development]. Almaty: KazNTU, 2013, 403 p.

5. Dyadin Yu.A., Gushchin A.L. Gazovye gidraty [Gas hydrates]. Soros Educational Journal, 1998, issue 3, pp. 5564.

6. Ezhi i nanostruktury [Hedgehogs and nanostructures]. Available at: http://youege.com/vysokie-texnologii/ezhi-i-nanostruktury (accessed 19 February 2015).

7. Klerks Zh., Zemskaya T.I., Matveeva T.V. other. Gidraty metana v poverkhnostnom sloe glubokovodnykh osadkov ozera Baykal [Methane hydrates in the surface layer of the deep-sea sediments of Lake Baikal]. Report of the Russian Academy of Sciences, 2003, vol. 393, issue 6, pp. 822826.

8. Makogon Yu.F. Prirodnye gazovye gidraty: rasprostranenie, modeli formirovaniya, resursy [Natural gas hydrates: distribution, pattern formation, resources]. Russian Chemical Journal, 2003, vol. 47, issue 3, pp. 7079.

9. Sergeev G.B. Nanokhimiya [Nanochemistry]. MSU, 2009.

10. Svidinenko Yu. Sistematicheskiy obzor sushchestvuyushchikh proektov nanoaktyuatorov [A systematic review of existing projects of nanoactuators]. Available at: http://www.microbot.ru/modules/Static_Docs/data/2_Nanotechnology/2_Basic_Technologies/_Actuators/031202_svidinenko_nanoactuator_rewiev/index.htm (accessed 19 February 2015).

11. Uchenye prodemonstrirovali printsip raboty molekulyarnykh nanomotorov [Scientists have demonstrated the principle of the molecular nanomotors]. Available at: http://persona.rin.ru/news/63902/f/uchenye-prodemonstrirovali-princip-raboty-

molekuljarnyh-nanomotorov (accessed 19 February 2015).

12. Foster L. Nanotekhnologii. Nauka, innovatsii i vozmozhnosti [Nanotechnology. Science, innovation and opportunity]. URSS, 2008.

13. Khavkin A.Ya. Nanoyavleniya i nanotekhnologii v dobyche nefti i gaza [Nanophenomena and nanotechnology in the production of oil and gas] ed. by corresponding member of RAS Safaralieva G.K. Moscow-Izhevsk: IIKI, 2010, 692 p.

14. Andrievsky G.V. et al. Colloidal Dispersions of Fullerene 60 in Water: Some Properties and Regularities of Coagulation by Electrolytes, The Electrochem. Soc. Interface, 195-th Meeting, Seattle, 1999.

15. Andrievsky G.V. et al. On the Production of an Aqueous Colloidal Solution of Fullerenes, J. Chem. Soc., Chem. Commun., 1995, pp. 12811282.

16. Andrievsky G.V. t al. FWS Molecular-colloid systems of hydrated fullerenes and their fractal clusters in water solutions. The Electrochemical Society Interface (195-th Meeting, May 26, 1999, Seattle, Washington) Spring 1999, Abs# 710.

17. Andrievsky G.V., Klochkov V.K., Karyakina E.L., Mchedlov-Petrossyan N.O. Studies of aqueous colloidal solutions of fullerene 60 BY electron microscopy. Chem. Phys. Lett, 1999, issue 300, pp. 392396.

32 622.276

- MPS REIS-H .. , 1

Novikov@tatnefteprom.ru

.. 2

bgroup8@.ru

.. 2 MVL@bg-inc.ru

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(>200 ) .

, - , - ( -). , .

, -- - . . , - - . - , , - - , - . - [2, 3, 4].

2014 . - - MPS REIS-H [1], - --, - .

MPS REIS-H

- - [5].

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-, , - ;

., , % /, % , 10-3 2

,

,

, 3/

, *

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34

AbstractIn article presented the analysis of the existing methods and technologies of remedial cementing and recommendations about carrying out of experimental works (EW) on water production restraining with new polymeric composition MPS REIS-H on deposits of carboniferous system Bashkir circle.The technology of EW carrying out with MPS REIS-H on wells of the Ivinsky field is considered in detail.

Materials and methodsWater solution of polymeric composition of MPS REIS-H, chrome acetate, geophysical surveys for definition of a source of the water coming to a well.

ResultsUse of the MPS REIS-H allowed to increase oil outputs by 8 times and to reduce water content by 2028%. Economic effect made 4048 thousand rubles per well.

ConclusionsAnalysis of this work allows us to conclude that the insulation technology of water using the new polymeric composition MPS REIS-H has a high scientific and technical level as against the previously tested and recommended composition for use at Tatnefteprom fields.

Keywordscarbonate reservoirs Bashkir-tier, the problem of high viscosity oil production (> 200sPa), water production restraining, new polymeric composition MPS REIS-H

Experimental works by polymeric composition MPS REIS-H to behind casing leaks response at Ivinsky fieldAuthors:Igor P. Novikov deputy deneral director, chief geologist1; Novikov@tatnefteprom.ruAlexander S. Primachenko deputy general director for technology service2; bgroup8@.ruMarina V. Lapshin leading specialist of new technologies2; MVL@bg-inc.ru

1"Tatnefteprom" JSC, Almetyevsk, Russian Federation2"Business Group" Ltd, Moscow, Russian Federation

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References1. Annual geological report of JSC

"Tatnefteprom." 2014, 14 .2. Bulatov A.I., Makarenko P.P., Proselkov Yu.M.

Burovye promyvochnye i tamponazhnye rastvory [Drill sludge and backfill fluids]. Moscow: Nedra, 1999, 424 p.

3. Bulatov A. I Tamponazhnye materialy i

tekhnologiya tsementirovaniya skvazhin [Cement materials and well cementing technology]. Moscow: Nedra, 1991, 336 p.

4. Malyarenko A.V., Zemtsov Yu.V. Metody selektivnoy izolyatsii vodopritokov v neftyanykh skvazhinakh i perspektivy ikh primeneniya na mestorozhdeniyakh Zapadnoy Sibiri [Selective isolation

methods of water influxes in oil wells and prospects of their application in the fields of Western Siberia]. Neftepromyslovoe delo, 1987, issue 1.

5. A.S. 1102895. 21 MKI E 33/138. Sostav dlya izolyatsii plastovykh vod v skvazhinu [Composition for the isolation of reservoir water into the well].

. - - , , , , , -. -

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15.02.2014 01.03.2014 04.06.2014

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- , - MPS REIS-H -- - .

1. . 2014. 14 c.

2. .., .., .. - . .: , 1999. 424 .

3. . . .: , 1991. 336.

4. .., .. // . 1987. 1.

5. .. 1102895. 21 33/138. .

35

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1. .., .., .., .. 2464470 , F16K 3/12 (2006/01); F16K 3/32 (2006/01). - .

29.06.2010; 20.10.2012. .29.

2. .., .., .. - // . 2013. 3. . 8082.

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AbstractCalculations and experimental research of hydraulic properties of shutoff and control valve are presented. The throughput ability was defined based on test value at modular cluster pump station which is facility of "Bashneft-Dobycha" and in laboratory of MKT-ACDM.

Materials and methodsMethod of calculation of hydraulic properties of shutoff and control valves based on Bernoulli's equation.

ResultsCalculation method, calculation and experimental value of hydraulic properties of shutoff and control valve on eighteen gate position are presented. Obtained properties of gate could be include in its datasheet.

Conclusions1. Obtained formulas could be used to calculation hydraulic properties of shutoff and control valves including design stage.

2. Calculations in ANSYS allow to visualize

flow motion in valve and it confirm formulas calculation results and outcome of experiment.

3. It is necessary to conduct further experimental research of hydraulic and cavitation properties to full opened valve position.

Keywordsgate valve, flow resistance, differential pressure, pressure loss, a course of a gate, throughput ability

The throughput ability of shutoff and control valvesAuthors:Ilgiz R. Chinjaev Ph.D., vice-president1; ruk_mkt@mail.ruAleksandr V. Fominykh Ph.D., professor2, head of laboratory1; prof_fav@mail.ruEgor A. Poshicalov chief designer1; poshivalov_79@mail.ruStanislav A. Sukhov manager of mechanical assembly production1; ooodok@bk.ru

1MKT-ACDM SPC, LLC, Kurgan, Russian Federation2Kurgan Agricultural Academy of T.S. Mal'cev, Kurgan, Russian Federation

UDC 621.646

ENGLISH VALVES

References1. Zaslavskij G.A., Rjazanov V.A., Chinjaev

I.R , Shanaurin A.L. Patent for invention 2464470 of the Russian Federation, MPK F16K 3/12 (2006/01); F16K 3/32 (2006/01). Stop-control gate valve. Declared 29.06.2010, published 20.10.2012, Bul. issue 29.

2. Chinjaev I.R., Fominykh A.V., Sukhov S.A.

Povyshenie nadezhnosti i effektivnosti raboty shibernoy zaporno-reguliruyushchey zadvizhki [Increase of reliability and overall performance of a stop-control gate valve]. Exposition Oil Gas, 2013, issue 3, pp. 8082.

3. Chinyaev I.R., Fominykh A.V. Eroshkin V.S., Kavitatsiya v shibernykh zadvizhkakh [Cavitation in gate valves]. Territoriya

neftegaz, 2013, Issue 5, pp.4849.4. Bashta T.M., Rudnev S.S., Nekrasov B.B., i

dr. Gidravlika gidromashiny i gidroprivody [Hydraulic of hydraulic machine and hydraulic gear]. Moscow: Mashinostroenie, 1982, 423 p.

5. GOST 55508-2013 Pipeline valves. Technique of the experimental definitions hydraulic and cavitation characteristics.

41 621.646

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info@tdmarshal.ru

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info@korsystem.ru

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ER CORROSOMETER probes Microcor corrosion monitoring Probes . , .

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, - ER CORROSOMETER probes Microcor corrosion monitoring Probes , - .

1. . CORROSOMETER 4020LT, 4021L 4001L.

2. Rohrback Cosasco Systems, Inc. Microcorp. : http://www.cosasco.com/documents/microcor_corrosion_monitoring_system_russian.pdf ( 09.02.2015)

3. Mark Smith, Nick Tucker. Microcor . RCS -. , 2011.

References1. Guidelines for the use. The transmitter and

receiver CORROSOMETER MODEL 4020LT, 4021L and 4001L.

2. Rohrback Cosasco Systems, Inc.

O sistemakh kompanii Microcorp [Systems Company Microcorp]. Available at: http://www.cosasco.com/documents/microcor_corrosion_monitoring_system_russian.pdf (accessed 09.02.2015)

3. Mark Smith, Nick Tucker. Interpretation probe readings Microcor in corrosion monitoring systems. RCS report in TNK-BP Moscow, 2011.

AbstractThe paper presents data on operating experience corrosion sensors type ER CORROSOMETER probes and Microcor corrosion monitoring Probes in highly aggressive environments.

Materials and methodsIn this work was applied a steel type 1018 ACME. Applied corrosion sensors are classified

as sensors working on ER method (metal loss).

ResultsThe article reflects the data obtained by monitoring the rate of corrosion in aggressive environments, using sensors and probes ER CORROSOMETER Microcor. Obtained data can give a correct interpretation of the results of monitoring the corrosion monitoring rate on oil and gas fields production.

ConclusionsArticle is extremely useful for professionals working in corrosion monitoring, for both understanding the operation of the sensors corrosion type ER CORROSOMETER probes and Microcor corrosion monitoring Probes in very aggressive environments, and for the correct selection of controls when performing anti-corrosion measures.

Experience of using corrosion sensors in corrosion monitoring systemsAuthors:Anatoliy N. Monakhov general director1; info@korsystem.ruAleksandr K. Kuznetsov deputy director1;Maria A. Monakhova general director2;

1"Korsystem" LLC, Moscow, Russian Federation2SIE "Eco-Chemical", Moscow, Russian Federation

UDC 620.193

ENGLISH CORROSION

50 620.193

.. ..., , 1

vtrui2008@mail.ru

.. ..., 1

rysionok@mail.ru

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lorapd@mail.ru

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tat.kuzinova@yandex.ru

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51

AbstractIt was suggested a combined corrosion inhibitor N-M-1 (gi) which is a mixture of contact and volatile forms with a common component. The material is the most effective if combined with hydrotest of equipment and conservation. It may also be recommended for the temporary protection of pipe's internal surfaces in the factory and field conditions.

Materials and methodsTo study the protective capability of the inhibitor was used the method of accelerated corrosion

tests simulating the conditions in a sealed container.

Results1. A corrosion inhibitor N-M-1 is an analogue of M-1 and compatible with various bases conservation compositions.

2. Modification of the N-M-1 (gi) exhibit enhanced barrier properties in comparison with analogue.

Conclusions1. Atmospheric corrosion inhibitor N-M-1

(gi) is effective to steel protection from electrochemical and microboilogical corrosion and may be used as universal addition for all type preservatives.

2. Experimental studies are shown that N-H-1(gi) is recommended for preservation of pipes and equipment internal surfaces instead of import analogue Cortec VpCI-649 BD.

Keywordscapacitive equipment, pipes, atmospheric corrosion inhibitor N-M-1 (gi)

Corrosion inhibitor for the preservation internal surfacesAuthors:Valeriy I. Trusov ph.d., professor, head of department1; vtrui2008@mail.ruRenata S. Krymskaya ph.d., assistant1; rysionok@mail.ruLora P. Danilovskaya ph.d., associate professor1; lorapd@mail.ruTatiana M. Kuzinova ph.d., senior researcher2; tat.kuzinova@yandex.ru

1State Marine Technical University of St.Petersburg, St. Petersburg, Russian Federation2Scientific-Production Association "Neftekhim" LLC, St. Petersburg, Russian Federation

UDC 620.193

ENGLISH CORROSION

References1. Krymskaya R.S., Trusov V.I., Altsybeeva A.I.,

Kuzinova T.M., Garmashova I.V., Bogdanova S.E. Ingibitor korrozii N-M-1 [Corrosion Inhibitor H-M-1]. Corrosion: materials,

protection, 2011, issue 9, pp. 3235.2. Trusov V.I., Krymskaya R.S., Bogdanova

S.E. Ekologicheski i tekhnicheski bezopasnye tekhnologii vodnoy konservatsii oborudovaniya neftyanoy

otrasli [Environmental and technical safety technology of water conservation equipment in oil industry]. Natural and engineering sciences, 2011, issue 6 (56), pp. 332336.

. 3, -, - 982% - (9:1) 7% (4 ).

- -222 (-8 9.014), -0 ( 9.014) 7,8 15150 1 . ~2 . ( ~ 100% ) (-9 9.014): - 5 .

- 45 . -649, 2- --1 --20 2,5 --1(). - . , - , - - --1.

, :1. , , -649;

2. --1 OH;

3. - -

;4. () , . -

1%- --1(), . - , - --1(). -, , () 10% .

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- - , .

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2. --1() - .

1. --1() - .

2. - --1() -649.

1. .., .., .., .., .., - .. --1 // : , . 2011. 9. . 3235.

2. .., .., ... - - // - . 2011. 6 (56). . 332336.

52 620.193

.. ..., 1

Lenchenkoval@mail.ru

.. . . ., 2

arepstein@mail.ru

.. 2

2999777@bk.ru

.. 2

project-consultinggroup@bk.ru

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.

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53

AbstractAt present time the corrosion is a cause of serious hazard to the downhole equipment.It should be noted that the traditional protection technology of borehole equipment, such as injection of the inhibitor through annulus or dosing capillary tubes in this case ineffective.In this regard the current task is development of devices that allow preventing corrosion.

Materials and methodsFor solution of such problems was used a routine analysis that is common method the oil and gas fields production.

ResultsDevice for anticorrosive protection of downhole pumping unit was developed on base of electrochemical protection method. The device is an alternative to chemical methods and provides corrosion protection at

the time of wells production.

ConclusionsThe efficiency of the anticorrosive protection device for downhole pumping unit is proved during laboratory, bench and pilot tests.

Keywordswell, corrosion, electrochemical protection, downhole pumping unit

Device of electrochemical anticorrosive protection for downhole pumping unitAuthors:Lubov E. Lenchenkova Ph.D., professor1; Lenchenkoval@mail.ruArkadiy R. Epsteyn Ph.D, chief constructor2; arepstein@mail.ruAskar R. Mavzyutov managing director2; 2999777@bk.ruArtur I. Akhetov leading engineer2; project-consultinggroup@bk.ru

1Ufa State Petroleum Technological University, Ufa, Russian Federation2Project-consulting group BK Ltd, Ufa, Russian Federation

UDC 620.193

ENGLISH CORROSION

References1. Valyushok A.V. O katodnoy zashchite

skvazhinnogo i pogruzhnogo oborudovaniya [About cathodic protection of the downhole and submersible equipment]. Territoriya neftegaz, 2010, issue 2, pp. 3034.

2. Kruman B.B., Krupitsyna V.A. Korrozionno-mekhanicheskiy iznos oborudovaniya [Corrosive and mechanical wear of equipment]. Moscow: Mashinostroyeniye, 1968, 104 p.

3. Ulig G.G., Revi R.U. Korroziya i bor'ba s ney. Vvedenie v korrozionnuyu nauku i tekhniku [Corrosion and Control. Introduction into corrosion science and technique]. Translated from English under A.M. Sukhotina editorship. Leningrad: Khimija, 1989, 456 p.

4. Daminov A.A. Korroziya podzemnogo oborudovaniya dobyvayushchikh skvazhin, oborudovannykh UETsN [Corrosion of the underground equipment in producing wells equipped with ECPU].

Territoriya neftegaz, 2009, issue 8. pp. 3236.

5. Useful model patent 80190 Ustroystvo zashchity pogruzhnoy nasosnoy ustanovki ot korrozii [Device of anticorrosive protection for downhole pumping unit]. Russian Federation, MPK E 21 V 43/00.

6. Useful model patent 119412 Ustroystvo zashchity pogruzhnoy nasosnoy ustanovki ot korrozii [Device of anticorrosive protection for downhole pumping unit]. Russian Federation, MPK E 04 V 43/00.

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3. .., .. . : . . . . .. -. .: , 1989. 456 .

4. .. - , - // . 2009. 8. . 3236.

5. 80190 - - . , 21 B 43/00.

6. 119412 . , F 04 B 43/00.

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1. , 4+ . : http://energyfuture.ru/otlichnyj-obzor-po-obemam-szhigaemogo-png-i-poter-ch4shflu ( : 17.02.2015)

2. . : http://poisk.livejournal.com/534455.html ( 17.02.2015)

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4. ., . // . . ., 2009. . 1. 26 .

5. .., .., .. // , 2013. 3.

6. // [ ]. : http://sintheticfuel.com/nng ( 17.02.2015)

AbstractIt is proposed a new process and equipment for gas/vapor recovery at last stage of oil separation to obtain commercial product broad fraction of light hydrocarbons (NGL) directly at oil fields. The process is based on compression of low pressure gas and "hot" separation of condensate in a multipurpose separator developed by the authors. The method is available for recovering of combination gases and in gas industry in a late stage of gas production at specific hydrocarbon deposits.

Materials and methodsComputer-aided study of mass-exchange

processes in the course of contact degassing and fractionating of low pressure gases from oil separation at a modern computer complex taking into account feed stock composition, actual loadings and technological parameters in the course of oil and low pressure gases treatment.

ResultsIt is proposed a new waste-free process and equipment for processing of low-temperature gases at oil separation. NGL obtained using the developed process and equipment is valuable feed stock for petrochemicals production. It can be used for production of liquefied hydrocarbon gases (LHCG) and stable gas condensate or

LHCG and fatty semi-finished product suitable for compounding with stock-tank oil to increase its gasoline potential at producing of ASKT condensed aviation fuel.

ConclusionsThe developed method of low pressure petroleum gas processing to obtain commodity NGL can find practical application by subsoil users at implementation of Gas programs.

Keywordslow pressure gas, separation, condensation, unstable gas condensate, broad fraction of light hydrocarbons (NGL)

Efficient utilization technology of petroleum gas at oil separation last stage

Authors:Ilmer yu. Khasanov ph.d, professor1 ; npc-sherik@mail.ruBoris S. Zhirnov ph.d., professor, head of chemical-engineering processes department2; jbc2@mail.ruUral R.Ilyasov ph.d., associate professor, vice-principal for Academic Affairs3; ilyasovu@gmail.comVladimir I.Rogozin ph.d., associate professor of chemical-engineering processes department4; npc-sherik@mail.ru

1Bashkir State University, Sterlitamak Branch, Sterlitamak, Russian Federation2Ufa State Petroleum Technological University (USPTU), Salavat Branch; Salavat, Russian Federation3USPTU, Ishimbay Branch; Ishimbay, Russian Federation4USPTU, Salavat Branch, Salavat, R