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April 2016




Geology and geologo-prospecting works


I.V. Goncharov, V.V. Samoilenko, N.V. Oblasov, M.A. Veklich, S.V. Fadeeva (TomskNIPIneft JSC, RF, Tomsk)
The role of different types of migration in the formation of oil and gas fields in Western Siberia (geochemical data)

Key words: Bazhenov formation, geochemistry, migration, oil and gas fields

We consider regional features of various types of hydrocarbon migration in the formation of oil and gas fields in Western Siberia. It is noted that in the case of primary migration of hydrocarbons generated Bazhenov formation, into the underlying reservoir, the driving force of secondary migration may not only be a difference of density of oil and water, but also the pressure difference in the Bazhenov formation and lower-lying collectors.
References
1. Goncharov I.V., Oblasov N.V., Smetanin A.V. et al., Genetic types and nature
of fluid of hydrocarbon deposits south-east of Western Siberia (In Russ.),
Neftyanoe khozyaystvo = Oil Industry, 2012, no. 11, pp. 8-13.
2. Tissot B., Welte D., Petroleum formation and occurrence, Springer, Heidelberg,
1978.
4. Kontorovich A.E., Surkov V.S., Trofimuk A.A. et al., Neftegazonosnye
basseyny i regiony Sibiri (Oil and gas basins and regions of Siberia), Part 2. Zapadno-Sibirskiy basseyn (West Siberian Basin), Novosibirsk: Publ. of INGG SO RAN, 1994, 201 p.
3. Goncharov I.V., Oblasov N.V., Samoylenko V.V. et al., The use of geochemical surveys in the estimation of reserves and development of oil and gas-condensate fields (In Russ.), Nedropol'zovanie XXI vek, 2012, no. 5, pp. 50-55.
5. Kontorovich A.E., Andrusevich V.E., Afanas'ev S.A. et al., Geology and formation
conditions of giant Tallinn gas-oil accumulation area in the Lower
Jurassic continental sediments (In Russ.), Geologiya i geofizika = Russian Geology and Geophysics, 1995, no. 6, pp. 5-28.
6. Moskvin V.I., Danilova V.P., Kostyreva E.A. et al., Sources of oil in pools of the Shaim petroliferous area (West Siberia) (In Russ.), Geologiya i geofizika = Russian Geology and Geophysics, 2004, no. 6, pp. 730-741.
7. Strizhnev K.V., Cherevko M.A., Sitnikov A.N. et al., Geological characterization of Bazhenov-Abalak Formation on the example of Paliynovskoye area of Krasnoleninskoye oil field (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2013, no. 12, pp. 24-27.
8. Zhil'tsova A.A., Isaev V.I., Korzhov Yu.V., Vertical geochemical zonality of
oil6and6gas complex (by the example of Rogozhnikovsky and Severo6Rogozhnikovsky
fields) (In Russ.), Izvestiya Tomskogo politekhnicheskogo universiteta
= Bulletin of the Tomsk Polytechnic University, 2013,V. 322, no. 1, pp. 69-82.
9. Goncharov I.V., Samoylenko V.V., Oblasov N.V. et al., Catagenesis of organic
matter Bazhenov Formation rocks in the south-east of West Siberia
(Tomsk region) (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2013, no. 10,
pp. 32-37
10. Goncharov I.V., Korobochkina V.G., Oblasov N.V., Nature of hydrocarbon
gases in the southeast of western Siberia (In Russ.), Geokhimiya = Geochemistry
International, 2005, no. 8, pp. 892-898.
11. Atlas mestorozhdeniy nefti i gaza Khanty-Mansiyskogo avtonomnogo okruga – Yugry (Atlas of oil and gas fields of Khanty-Mansi Autonomous District - Yugra): edited by Volkov V.A., Shpil'man A.V., Tyumen': Publ. of V.I. Shpilman research
and analytical Centre for the rational use of the subsoil, 2013, 236 p.
12. Mangazeev V.P., Stepanova G.S., Fomin A.I. et al., Problems of development of Lomovoe field (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2006, no. 1, pp. 42-47.
13. Goncharov I.V., Samoylenko V.V., Oblasov N.V. et al., Nature of oils for par of Vankorskoye oilfield (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2011, no. 3, pp. 12-17.
14. Goncharov I.V., Geokhimiya neftey Zapadnoy Sibiri (Geochemistry of oil
of Western Siberia), Moscow: Nedra Publ., 1987, 181 p.
15. Nemchenko-Rovenskaya A.S., Ryl'kov A.V., Khafizov F.Z. et al., Geologicalgeochemical
parameters of the oil-and-gas content forecast on greater
depths of northern areas of Western Siberia (In Russ.), Nedropol'zovanie
XXI vek, 2011, no. 4(29), pp. 30-35.
16. Fomin A.N., Katagenez organicheskogo veshchestva i neftegazonosnost'
mezozoyskikh i paleozoyskikh otlozheniy Zapadno-Sibirskogo megabasseyna
(Catagenesis of organic matter and oil and gas potential of Mesozoic and
Paleozoic deposits of the West Siberian Megabasin), Novosibirsk: Publ. of
INGG SO RAN, 2011, 331 p.

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V.P. Maximov, A.Yu.Chesalov, A.V. Bobrov, A.V. Bychkov (TomskNIPIneft JSC, RF, Tomsk), V.S. Zhuzhel (Rosneft Oil Company OJSC, RF, Moscow), N.V. Denisov Tomskneft VNK JSC, RF, Tomsk)
Seismic exploration work efficiency improvement on the example of project on license area of Tomskneft VNK JSC

Key words: method of field survey, processing and interpretation of seismic data, spectral decomposition of seismic data.

The authors consider the problem of reliability improvement of seismic models, which are formed during seismic survey using traditional technologies. Quality and reliability of seismic models can be improved by method optimization, strong control of field survey quality, enhancement of seismic data processing, improvement of seismic data interpretation, integration of cross-sectional results, and efficient actualization of seismic models according to drilling results. These measures allow not only refine models of known oil deposits and oil fields into Jurassic-Cretaceous formation and increasing effectiveness of engineering, but also allocate other perspective objects.
References
1. Metodicheskie rekomendatsii po ispol'zovaniyu dannykh seysmorazvedki
(2D, 3D) dlya podscheta zapasov nefti i gaza (Guidelines on the use of seismic data (2D, 3D) for calculating oil and gas reserves), Moscow: Publ. of Gers, 2006, 39 p.
2. Metodicheskie rekomendatsii po ispol'zovaniyu dannykh seysmorazvedki
dlya podscheta zapasov uglevodorodov v usloviyakh karbonatnykh porod s
poristost'yu treshchinno-kavernovogo tipa (Guidelines on the use of seismic
data to calculating hydrocarbon reserves in conditions of carbonate rocks
with a fracture-cavern porosity): edited by Levyant V.B., Moscow: Publ. of
Gers, 2010, 250 p.
3. Bobrov A.V., Ivanitskiy M.Yu., Utochnenie modeli mestorozhdeniya s pomoshch'yu tekhnologii spektral'noy dekompozitsii PO DECISIONSPACE (LANDMARK)
(Clarification field model using spectral decomposition technology
on software DECISION SPACE(LANDMARK)), Proceedings of V International scientific and practical conference EAGO “Geokrym-2015. Problemy neftegazovoy geologii i geofiziki” (Geokrym 2015. Petroleum geology and geophysics problems), Alushta, 2015, pp. 176–179.

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S.V. Parnachev, D.V. Vorobiev, I.V. Goncharov, A.G. Skripkin (TomskNIPIneft JSC, RF, Tomsk), Zakharov SV (Tomskneft VNK OJSC, RF, Tomsk)
Perspectives of Bazhenov formation oil productivity in Tomsk Region


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M.V. Shaldybin (TomskNIPIneft JSC, RF, Tomsk), V.A. Kolesov (RN-KrasnoyarskNIPIneft LLC, RF, Krasnoyarsk), S.V. Parnachev, S.Yu. Filimonov (TomskNIPIneft JSC, RF, Tomsk)
Mechanostratigrapical approach for Preobrazhen carbonate reservoirs (Eastern Siberia, Russia) core analysis


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Working out and operation of oil deposits


A.V. Kuznetsov, P.V. Molodykh, O.Yu. Matveyev, A.Yu. Megalov, A.S. Aleshkin (TomskNIPIneft JSC, RF, Tomsk), S.V. Zakharov (Tomskneft JSC, RF, Tomsk Region)
Improvement of approaches to evaluation of well - formation system parameters as the part of Tomskneft VNK JSC reservoir management

Key words: reservoir management, well test monitoring management, alternative sources of information

One of the keys in effective reservoir management is having precise information about well - formation system in total and formation pressure in particular. This demands a sufficient amount of wells to be covered by ‘classic’ well test investigations, which, on the other hand, brings company to irretrievable oil production loss. Being put into a dilemma the authors suggest an alternative ways for evaluating formation pressure, analyzing risks and benefits from their use.
References
1. Kremenetskiy M.I., Ipatov A.I., Gidrodinamicheskie i promyslovo-tekhnologicheskie issledovaniya skvazhin (Hydrodynamic and field technological research), Moscow: MAKS Press Publ., 2008, 476 p.
2. Barree R., Barree V., Craig D., Holistic fracture diagnostics: Consistent interpretation of prefrac injection tests using multiple analysis methods,
SPE 107877, 2009.
3. Craig D., Eberhard M., Barree R., Adapting high permeability sands for estimating reservoir engineering parameters, SPE 60291, 2000.
4. Blanc G.Le, Gunasan E., Boutaud de la Combe J-L., Jaffrezic V., Reservoir
characterization using injection test after-closure analysis: field case history in
a depleted oil reservoir, SPE 128052, 2010.
5. RD 153-39-023-97, Pravila vedeniya remontnykh rabot v skvazhinakh (Rules for repair work in wells), Moscow: Publ. of Mintopenergo RF, 1997.
6. Koshovkin I.N., Kuznetsov A.V., Molodykh P.V. et al., Implementation of organizational and methodical approaches to reservoir management of Tomskneft VNK JSC (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2014, no. 12,
pp. 120-124.

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A.G. Skripkin (TomskNIPIneft JSC, RF, Tomsk), K.V. Toropov (Rosneft Oil Company OJSC, RF, Moscow)
Laboratory research of ASP flooding on core plugs of Mamontovskoe oilfield


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P.A. Glazunov, A.B. Fedorova, A.V. Smetanin, A.A. Gorkaltsev, S.V. Pylnik (TomskNIPIneft JSC, RF, Tomsk)
The summary of oil displacement experiments in Tomsk region


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Designing of arrangement of deposits


A.V. Vykhodtsev (TomskNIPIneft JSC, RF, Tomsk), A.A. Kaverin (Rosneft Oil Company OJSC, RF, Moscow)
Using of conceptual design for integrated approach to the development and long-term planning of oil and gas fields


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I.P. Glyzin, E.V. Kolesnikova, S.O. Markov, M.P. Shchegolikhina (TomskNIPIneft JSC, RF, Tomsk)
The role of historical and cultural research in system design of oil and gas facilities (TomskNIPIneft JSC experience)


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Information technology


V.Z. Kuzenkov, A.N. Rymshin, N.A. Povalkovich, M.V. Kovin (TomskNIPIneft JSC, RF, Tomsk)
Engineering Document Management System: the experience of the development and implementation

Keywords: design and survey work, management, electronic document management, automation

The paper describes the experience of the development and implementation of systems engineering workflow in the TomskNIPIneft JSC. This system is used to optimize processes and improve management efficiency and control tasks in the preparation of design and estimate documentation arrangement of objects of oil and gas deposits.
References
1. Sutton M.J.D., Document management for the enterprise: principles, techniques and applications, New York: John Wiley & Sons, Inc., 1996.
2. Kuzenkov V.Z., Structural description supervisory control engineering document project companies (In Russ.), Mezhdunarodnyy nauchno-issledovatel'skiy zhurnal, 2015, no. 7(38), pp. 60-62.
3. Kuzenkov V.Z., Liepin'sh A.V., Povalkovich N.A. et al., Fields construction projects
management on the basis of engineering documents circulation system
in TomskNIPIneft OJSC (In Russ.), Neftyanoe khozyaystvo = Oil Industry,
2010, no. 9, pp. 110-113.

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I.A. Khristolyubov, A.A. Napryushkin (TomskNIPIneft JSC, RF, Tomsk), S.A. Egorov, V.B. Kalashnikova (East-Siberian Oil and Gas Company JSC, RF, Krasnoyarsk)
Geoinformation systems for land-use and land rent data management in oil and gas production company


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From history of development of petroleum industry



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Economy, management, law


S.V. Buchinskiy, V.S. Filatov, I.Sh. Fomenko (TNNC LLC, RF, Tyumen), S.V. Romachkin ROSPAN INTERNATIONAL JSC, RF, New Urengoy)
A modern approach to the management of scientific and technical project to support reservoir development

Key words: project management, planning, network schedule

The authors of the article describe the project management process using a case study of the interaction of a gas producer ROSPAN INTERNATIONAL and the Tyumen Petroleum Research Center (TNNC) when supervising the reservoir studies on Vostochno-Urengoysky, Novo-Urengoysky, and Resursny license areas. The article describes the principles of formation and application of integrated-schedule models using Microsoft Project software.

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Geology and geologo-prospecting works


N.G. Nurgalieva, N.A. Ikhsanov, D.K. Nurgaliev, A.N. Dautov (Kazan (Volga Region) Federal University, RF, Kazan)
Facial characteristics of the Ufimian bituminous sediments


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Drilling of chinks


R.V. Karapetov, S.A. Gromadskiy, Hoang Quok Khanh (Vietsovpetro JV, the Socialist Republic Vietnam, Vungtau)
The perspectives of introduction the cementless well completion technology in Vietsovpetro JV

Key words: well, well completion, liner, cementless well completion, casing hardware, packer, production port

The authors describe in details the technological approaches for cementless well completion, providing for improvement of oil fields development and operation processes. The article covers benchmarking analysis of various technical and technological decisions implemented for cementless well completion. Prospectivity assessment is carried out for wide implementation of the cementless completion technology under Vietsovpetro JV fields conditions.
References
1. Shakhmin A.M., Nabukhayushchie elastomernye pakery (Swellable elastomer packers), Proceedings of conference “Molodaya neft' 2014” (Young
Oil 2014), URL: http://conf.sfu-kras.ru/sites/oil2014/3.html
2. Iskhakov A.R., Opyt primeneniya vodoneftenabukhayushchikh zakolonnykh pakerov (Experience in the use of water-oil-swellable casing packers), Proceedings of TatNIPIneft'», URL: http://www.tatnipi.ru/sms_2011_2.html

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N.M. Ulyasheva, Yu.L. Logachev, A. M. Voronik, D.V. Khodenko (Ukhta State Technical University, RF, Ukhta)
Features design technology deepening and drilling fluids during well construction in lithified clay rocks

Key words: drilling mud, clayey shale, borehole profile, assembly of drilling string bottom

Drilling companies often have problems during horizontal wells constructions such as abnormal geological conditions bringing WOB, high coefficient of friction in directional of wells, cleaning of well from cutting and etc. On the example of Michayuskoe field we provide complex solutions of these problems. They are directed to safekeeping the stability of lithified clays rocks by increasing inhibitory and bridging abilities of clay-free drilling mud. This type of mud is composed of potassium inhibitor with high molecular weight, polysaccharides, organic inhibitor and carbon black. Frictions forces (or resistance to movement of the boring tool) are evaluated to optimize the composition of the drilling layout boring tool while drilling in directional wells. This solution takes into account placement of steel drill pipe and heavyweight drill pipe with considering power options, borehole profile, and parameters of drilling mud. While noting considerable attention should be paid to the lubrication of drilling mud since its effect will be significant for coefficient of friction in horizontal parts of wells.
References
1. Akhmadeev R.G., Danyushevskiy V.S., Khimiya promyvochnykh i tamponazhnykh zhidkostey (Chemistry of flushing and grouting fluids), Moscow: Nedra Publ., 1981, 152 p.
2. Bondarev V.P., Geologiya (Geology), Moscow: FORUM-INFRA Publ., 2004, 224 p.
3. Luk'yanov V.T., Razvitie teorii upravleniya iskrivleniem skvazhin pri burenii (Development of the wells curvature control theory while drilling): thesis of doctor of technical science, Krasnodar, 1988.

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I.A. Arutyunov, A.V. Kulik, S.N. Potapova, D.V. Svetikov, E.V. Korolev, O.L. Ivanisko (United Research and Development Centre LLC, RF, Moscow)
Production of synthetic component of drilling fluids


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<table border="0" summary="" width="100%" bgcolor="#000066">
  <tbody>
    <tr><td><b><font color="#ffffff" face="Arial">Working out and operation of oil deposits</font></b></td></tr>
   </tbody>
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N.A. Gultyaeva (Tyumen Branch of SurgutNIPIneft, RF, Tyumen), O.V. Fominykh, A.S. Samoilov, R.R. Sabitov (Tyumen Industrial University, RF, Tyumen)
Study of gas-oil ratio simulation methods


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V.V. Bushuev, A.A. Vdovina (Globalization and Sustainable development. Institute of Energy Strategy CJSC, RF, Moscow)
Synthesis of field development technologies, taking into account their environmental characteristics of the structure and potential of hydrocarbons


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M.S. Khozyainov, D.A. Chernokozhev, M.I. Kuznetsov, K.I. Kuznetsov (MANTSGEO LLC, RF, Moscow; Dubna State University, RF, Dubna)
Evaluating the effectiveness of leveling of injectivity profile on the results of indicator research


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O.V. Salimov, A.V. Nasybullin (TatNIPIneft, RF, Bugulma), V.G. Salimov (Volga-Kama Local Section of Russian Academy of Natural Sciences, RF, Bugulma)
Unified design of induced fractures with variable permeability

Key words: acid fracturing, fracture conductivity, unified design

Feasibility of the unified design concept for induced fractures with permeability dictated by fractures’ geometries has been shown. Reasoning for the acid fracturing unified design concept is offered, as well as a methodology for calculation. The developed methodology is an effective tool for optimizing acid fracturing treatment, justification of the treatment volume and effectiveness prediction even at the stage of well planning.
References
1. Economides M., Oligney R., Valko P., Unified fracture design. Bridging the
gap between theory and practice, Orsa Press, Alvin, Texas, 2002, 262 p.
2. Mahdiyar H., Jamiolahmady M., Danesh A., New mechanical and
damage skin factor correlations for hydraulically fractured wells, SPE
107634, 2007.
3. Cinco-Ley H., Samaniego-V.F., Transient pressure analysis: Finite conductivity
fracture case versus damage fracture case, SPE 10179, 1981.
4. Nierode D.E., Kruk K.F., An evaluation of acid fluid loss additives, retarded
acids, and acidized fracture conductivity, SPE 4549, 1973.
5. Khisamov R.S., Salimov O.V., Borisov G.A., Salimov V.G., Experimental
study of acid fracture conductivity as a function of confining stress (In
Russ.), Neftyanoe khozyaystvo = Oil Industry, 2015, no. 6, pp. 58-61.
6. Meyer B.R., Jacot R.H., Pseudo-steady state analysis of finite conductivity
vertical fractures, SPE 95941, 2005.
7. Williams B.B., Nierode D.E., Design of acid fracturing treatments,
J. Petr. Tech., 1972, no. 7 (July), pp. 849-859.
8. Roberts L.D., Guin J.A., A new method for predicting acid penetration
distance, Soc. Pet. Eng. J., 1975, no. 15(4), Aug., pp. 277-286.

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K.A. Turegeldieva, U.K. Zhapbasbayev, B.K. Assilbekov (Kazakh-British Technical University, Kazakhstan, Almaty), A.B. Zolotukhin (Gubkin Russian State University of Oil and Gas, RF, Moscow)
Matrix acidizing modeling of near-wellbore with reduced reservoir properties (part 2)

Key words: acid stimulation, damage function, wormhole, Damkohler number

This paper deals with two-scale numerical modeling of the carbonate rock dissolution using hydrochloric acid. In order to account the reduced reservoir properties due to of the near-wellbore zone damage, a special function fd characterizing reservoir damage introduced in the numerical calculations. The influence of fd function on process of rock dissolution depending on the Damkholer number is analyzed based on numerical modeling. The optimal regimes of damaged and undamaged carbonate rock dissolution were determined.


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S.A. Vakhrushev, А.Е. Folomeev (BashNIPIneft LLC, RF, Ufa), Yu. A. Kotenev (Ufa State Petroleum Technical University, RF, Ufa), R. M. Nabiullin (Bashneft-Polus LLC, RF, Ufa)
Acid treatment with diverting on carbonate reservoirs of R. Trebs oil field


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D.V. Novokreshchennykh, A.V. Raspopov (PermNIPIneft Branch of LUKOIL-Engineering LLC in Perm, RF, Perm)
Efficiency of radial drilling and acidizing technologies in carbonate reservoirs of Perm region

Key words: carbonate, stimulation of production, radial drilling, acidizing

This article focuses on experience of radial drilling and acidizing technologies in similar geological and hydrodynamic conditions. Main advantages of radial drilling are shown in analysis of oil production rate and productivity index. In paper oil production after treatments for the same period of well operation is compared.
References
1. Raspopov A.V., Kondrat'ev S.A., Novokreshchennykh D.V., The influence of geological and physical conditions on the efficiency of radial canals drilling into the borehole zone of reservoir (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2012, no. 3, pp. 78-79.
2. Raspopov A.V., Novokreshchennykh D.V., Comparative analysis of technological efficiency of oil recovery stimulation methods on the carbonaceous reservoirs (In Russ.), Vestnik TsKR Rosnedra, 2013, no. 4, pp. 52-56.
3. Antonov D.V., Kondrat'ev S.A., Zhukovskiy A.A., Kochneva T.S., Experience of hydraulic fracturing in the deposits of Perm region and the main directions of improving its efficiency (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2014, no. 3, pp. 70-72.
4. Viktorin V.D., Lykov N.A., Razrabotka neftyanykh mestorozhdeniy, priurochennykh k karbonatnym kollektoram (Developing oil fields associated
with carbonate reservoirs), Moscow: Nedra Publ., 1980, 202 p.

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D.G. Podoprigora, L.A. Shangaraeva (National Mineral Resources University (Mining University), RF, Saint-Petersburg), A.V. Usenkov, P.Yu. Ilyushin (Perm National Research Polytechnic University, RF, Perm)
Development of acid composition for bottom-hole formation zone treatment at high reservoir temperatures


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Designing of arrangement of deposits


A.F. Mozhchil, S.V. Tretyakov, D.E. Dmitriev, N.Z. Gilmutdinova, S.V. Esipov, A.A. Karachev (Gazpromneft NTC LLC, RF, Saint-Petersburg)
Technical and economic optimization of well pads calculation at the stage of integrated conceptual design

Key words: integrated conceptual design, well pad calculation, CAPEX optimization, cost engineering

At the stage of conceptual design, when engineering decisions have maximum impact on the overall project economical results, one of the key issues is to determine optimal number of well pads with regard to well drilling and platform building costs. Well pads calculation method for various field development systems is presented that consider drilling unit deadweight, well design restrictions, wells collision risk minimization and surface topographical restrictions. Calculation algorithm uses well drilling and number of pads minimization function or technical and economical optimization approach that takes into account production wells potential and cost of units.
References
1. Ismagilov R.R., Maksimov Yu.V., Ushmaev O.S. et al., Integrated model for complex management of reservoir engineering and field construction
(In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2014, no. 12, pp. 71-73.
2. Karsakov V.A., Tret'yakov S.V., Devyat'yarov S.S., Pasynkov A.G., Drilling cost
optimization during conceptual project phase of field development
(In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2013, no. 12, pp. 33-35.
3. Kharlamov K.N., Sheshukova G.N., Kushmanov P.V., Features of profiling of
horizontal and multihole wells boreholes at the automated design of their well
heads clustering schemes (In Russ.), Neftyanoe khozyaystvo = Oil Industry,
2006, no. 4, pp. 30-32.
4. Amorin R., Broni-Bediako E., Application of minimum curvature method
to wellpath calculations, Res. J. Appl. Sci. Eng. and Tech., 2010, no. 2(7),
pp. 679-686.
5. Khasanov M.M., Sugaipov D.A., Ushmaev O.S., Development of cost engineering in Gazprom Neft JSC (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2013, no. 12, pp. 14-16.
6. Khasanov M.M., Sugaipov D.A., Zhagrin A.V. et al., Improvement of CAPEX estimation accuracy during early project stages (In Russ.), Neftyanoe
khozyaystvo = Oil Industry, 2014, no. 12, pp. 22-27.

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Pipeline transport of oil


M.A. Morozov, A.V. Volkov, A.V. Ryzhenkov, A.G. Parygin, M.V. Lukin, A.V. Naumov (National Research University Moscow Power Engineering Institute, RF, Moscow)
Calculation of the pipeline systems according to the degree of hydrophobicity of internal surfaces


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Transport and oil preparation


A.A. Tarasenko, P.V. Chepur (Tyumen State Oil and Gas University, RF, Tyumen), Y. Guan, professor (China University of Petroleum, China, Beijing)
Performance evaluation of large tank RVSPK-100000 in development of differential settlement area

Key words: stress-strain state, RVSPK-100000, tank, ANSYS, foundation, base, settlement, differential settlement, SAG

In the article, the authors analyze the influence of inhomogeneity of subgrade zones on the stress-strain state of the unique reservoir RVSPK-100000. For the study used numerical methods in mechanics of solid deformable body, in particular the method of finite elements. The dependences of change of equivalent stress in structures bottom, front and additional stiffening rings RVSPK-100000 fr om the height of the wall, and the dependence of the value of the lim it on the length of the tank SAG.
References
1. Vaynshtok S.M., Novoselov V.V., Prokhorov A.D. et al., Truboprovodnyy transport nefti (Oil pipeline transport), Moscow: Nedra -Biznes-tsentr Publ., 2004, V. 2, 621 p.
2. Mustafin F.M., Zhdanov R.A., Karavaychenko M.G. et al., Rezervuary dlya
nefti i nefteproduktov (Tanks for oil and oil products), Part 1. Konstruktsii i
oborudovanie (Construction and equipment), St. Petersburg: Nedra Publ.,
2010, 480 p.
3. Konovalov P.A., Mangushev R.A., Sotnikov S.N. et al., Fundamenty stal'nykh rezervuarov i deformatsii ikh osnovaniy (Foundations of steel tanks and deformation of their bases), Moscow: Publ. of Izdatel'stvo Assotsiatsii stroitel'nykh vuzov, 2009, 336 p.
4. Tarasenko A.A., Chepur P.V., Tarasenko D.A., Numerical simulation of vertical steel tank deformation while differential settlements developing (In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2015, no. 4, pp. 88-91.
5. Tarasenko A.A., Chepur P.V., Chirkov S.V., Theoretical and experimental justification
of full lift method of tank 20000 m2 for repair its base and foundation
(In Russ.), Neftyanoe khozyaystvo = Oil Industry, 2016, no. 3, pp. 123-125.
6. Tarasenko A.A., Chepur P.V., Chirkov S.V., Study of inherent stiffness of veltical
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