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2018/3
New well logging-control technology in educational process
Geosciences

Authors: Oleg V. GORBATYUK graduated from the National Research Nuclear University in 1971 specializing in physical and power installations. He is Candidate of Physical and Mathematical Sciences, assistant professor of the Department of Geophysical Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). Area of research interests: nuclear geophysics, metrology, standardization and certification. At the present he works as Executive Secretary of the Technical Committee on Standardization ТК 431 (Geological Study, Exploration and Protection of Subsurface Resources), board member of the Euro-Asian Geosciences Organization (EAGO), and also Head of the EAGO certification body for geophysical products. He is author of more than 30 scientific publications. E-mail: gorbatyuk@eago.ru
Sergei P. SKOPINTSEV graduated from the Ryazan Radio Engineering Institute in 1972. He is Senior Lecturer at Department of Geology, Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the development of well logging equipment at oil and gas fields. He is author of more than 15 scientific publicat. E-mail: skopintsev.sp@gmail.com
Mariya S. KHOKHLOVA graduated from Gubkin Russian State University of Oil and Gas in 1999. She is Candidate of Geological and Mineralogical Sciences, associate Professor, senior lecturer of the Department of Geophysical Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). She is specialist in the interpretation of well logging data.
E-mail: khokhlova.ms@gubkin.ru

Abstract: In order to familiarize students with the methods of assessment and selection of measuring equipment used to conduct well geophysical studies, a set of trainingstands based on digital technologies with the use of up-to-date software and hardware was developed and successfully applied. These stands allow to explore the processes of obtaining and converting date using multifunctional highly productive digital devices. Since the stands are made according to a unified USB device scheme, this allows to reduce the use of unique specific software products when performing parameter measurements, telecasting and processing the received data by using public software such as Excel, Word, Paint

Index UDK: 550.8.012; 550.8.013

Keywords: digital technologies, educational process, calibration stand

Bibliography:
1. Tipovoy komplekt uchebnykh laboratornykh stendov po izmeritel’nym ustroystvam i ikh metrologii [Elektronnyy resurs]. Rezhim dostupa: http://ngsstend.blogspot.ru/
2. Morozov A.M., Morozov B.F., Skopintsev S.P. Metrologo-metodicheskoe obespechenie izmereniy temperatury i davleniya apparaturoy gazodinamicheskogo karotazha. Karotazhnik, 1999, no. 62, р. 92-105.
3. Skopintsev S.P. Apparatura GIS-kontrol’: Uchebnoe posobie. M.: Izdatel’skiy centr RGU nefti i gaza imeni I.M. Gubkina, 2014, p. 204.
4. Chekalyuk E.B. Termodinamika neftyanogo plasta. M.: Nedra, 1965, p. 240.
5. Zhuvagin I.G., Komarov S.G., Chernyy V.B. Skvazhinnyy termokonduktivnyy debitomer STD. M.: Nedra, 1973, p. 81.
6. Skvazhinnyy vlagomer. G.A. Belyshev, D.A. Bernshteyn, T.G. Gabdullin, I.G. Zhuvagin, T.G. Trufanov. Avtorskoe svidetel’stvo SSSR, no. 713994, 1980.
7. Skopintsev S.P. Vozmozhnosti magnitnogo lokatora muft pri issledovanii intervalov perforatsii. Karotazhnik, 2003, no. 105, p. 114-119.
8. Mishchenko I.T. Skvazhinnaya dobycha nefti. M.: Neft’ i gaz, 2003, p. 689.
9. Bagrintsev M.I. Sovremennoe sostoyanie promyslovo-geofizicheskikh issledovaniy deystvuyushchikh gazovykh i gazokondensatnykh skvazhin. M.: VIAMS, 1982, p. 52.
10. RD 153-39.0-072-01. Tekhnicheskaya instruktsiya po provedeniyu geofizicheskikh issledovaniy i rabot priborami na kabele v neftyanykh i gazovykh skvazhinakh. M., 2002.

2018/3
Identification of development of highly productive reservoirs based on geomechanical modeling process
Geosciences

Authors: Andrey V. GORODNOV graduated from Gubkin Moscow Institute of petrochemical and Gas Industry in 1978. He is Candidate of Geological and Mineralogical Sciences, associate professor of the Department of Geological Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of petrophysical modeling of complex geological objects. He is author of more than 90 scientific publiccations. E-mail: gorodnov.a@gubkin.ru
Nikolay Sh. RAVILOV graduated from Gubkin Russian State University of Oil and Gas Department in Tashkent in 2014. He is postgraduate student of the Department of Geological Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). His scientific interests include geomechanics of rocks. He is author of 7 scientific publications.
E-mail: ravilov_n@bk.ru
Galina M. ZOLOYEVA graduated from the Gubkin Moscow Institute of petrochemi- cal and Gas Industry in 1964. She is Doctor of Geological and Mineralogical Sciences, Professor of the Department of Well Logging of Gubkin Russian State University of Oil and Gas (National Research University). She is specialist in the field of petrophysical mo- deling and interpretation of logging data. She is author of more than 90 scientific publications. E-mail: galina.zoloeva@mail.ru

Abstract: In complex deposits with large angles of bedding and a sharp change in the thickness of the seams, zones of nonuniform stresses, leading to rock deformation, are formed. To identify such zones, various methods are used, one of which is geomechanical modeling. In the course of this work, a geological-geomechanical model of the productive reservoir of the oil field was constructed, over which areas with apparent extremes of stress concentrations were identified. The analysis of the wells performance and logging data showed that in areas with maximum stress concentrations rocks start fracturing, which results in a sharp increase in the productivity of the wells

Index UDK: 550.82

Keywords: geomechanical model, porosity, productivity, stress-strain state

Bibliography:
1. Bezrukov A.V., Ahmadullina D.R., Sovichev V.I., Emchenko O.V. Prognoz treshchinovatosti karbonatnyh rezervuarov na osnove rascheta napryazhennogo sostoyaniya geologicheskih tel. Neftyanoe hozyajstvo, 2012, no. 4, p. 18-20.
2. Dulaeva E.N., Shakirov R.I. Analiz zon razuplotnenij, vydelennyh razlichnymi metodami, v karbonatnyh kollektorah bashkirsko-serpuhovskih otlozhenij. Geologiya, razrabotka neftyanyh i neftegazovyh mestorozhdenij: Tezisy dokl. Bugul’ma, 2013.
3. Kashnikov Yu.A., Shustov D.V., Yakimov S.Yu. Razrabotka geologo-geomekhanicheskoj modeli turnej-famenskogo ob’ekta Gagarinskogo mestorozhdeniya//Neftyanoe hozyajstvo, 2013, no. 2, p. 50-54.
4. Kashnikov Yu.A., Ashihmin S.G. Mekhanika gornyh porod pri razrabotke mestorozhdenij uglevodorodnogo syr’ya. M.: Nedra, 2007, 467 p.
5. Kuznecov O.L. i dr. Preobrazovanie i vzaimodejstvie geofizicheskih polej v litosfere. M.: Nedra, 1990.
6. Zor’kin L.M., Kuznecov O.L. i dr. O prirode «kol’cevyh» fiziko-himicheskih anomalij v osadochnom chekhle. Dokl. AN SSSR, 1979, no. 2, t. 243, p. 477-480.
7. Paffengol’c K.N. Geologicheskij slovar’: v  2-h tomah. M.: Nedra, 1978, 456 p.
8. Petrov A.I., Shein V.S. O neobhodimosti ucheta sovremennoj geodinamiki pri ocenke i pereschete promyshlennyh zapasov nefti i gaza. Geologiya nefti i gaza, 2009, no. 11, p. 10-39.
9. Timurziev A.I. Strukturno-deformacionnye usloviya produktivnosti skvazhin na mestorozhdeniyah Zapadnoj Sibiri, oslozhnennyh sdvigovymi deformaciyami. Vestnik CKR Rosnedra, 2010, no. 5, p. 47-58.
10. Timurziev A.I. Tekhnologiya prognozirovaniya treshchinovatosti na osnove trekhmernoj geomekhanicheskoj i kinematicheskoj modeli treshchinnogo kollektora. Geofizika, 2008, no. 3, p. 41-60.

2018/3
Information and technical support for reservoir management in national oil and gas producing companies
Geosciences

Authors: Andrey I. IPATOV graduated from Gubkin Russian State University of Oil and Gas in 1982. Doctor of Technical Sciences, Professor of the Department of Geophysical Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). Specialist in the field of geophysical and hydrodynamic control of development of oil and gas fields.
E-mail: ipatov.ai@gazprom-neft.ru
Victor G. MARTYNOV graduated from Gubkin Moscow Institute of Petrochemical and Gas Industry in 1975. He is Doctor of Economics, Rector of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of geophysics, human resource management and economics. He is author of more than 150 scientific publications.
E-mail: v.martynov@gubkin.ru
Danila N. GULYAEV graduated from Gubkin Russian State University of Oil and Gas in 2001. Candidate of Technical Sciences, Associated Professor of the Department of Geophysical Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). Specialist in reservoir management and oil and gas fields development.
E-mail: letter_to_me@rambler.ru
Mikhail I. KREMENETSKIY graduated from Gubkin Russian State University of Oil and Gas in 1973. Doctor of Technical Sciences, Professor of the Department of Geophysical Information Systems of Gubkin Russian State University of Oil and Gas (National Research University). Specialist in the field of geophysical and hydrodynamic control of development of oil and gas fields.
E-mail: kremenetskiy.mi@gazpromneft-ntc.ru
Sergey F. KHAFIZOV graduated from Gubkin Russian State University of Oil and Gas in 1987. Doctor of Geological and Mineralogical Sciences, Professor of the Department of Geology of Petroleum Systems of Gubkin Russian State University of Oil and Gas (National Research University). He specializes in the field of petroleum geology, associated with the development of complex reservoirs, formation conditions and prognosis of unstructured hydrocarbon traps. E-mail: khafizov@gubkin.ru
Alexander A. RIDEL graduated from Tyumen State University in 2003. Head of the Department for Interpretation and Analysis of Well Testing, Gazpromneft NTC. Specialist in the field of well testing. E-mail: trydyrgy@gubkin.ru

Abstract: A systematic approach to reservoir management at a vertically integrated oil company is presented, the informative value and effective implementation of the permanent reservoir monitoring is described and the results are shown, which are expressed in the production and field recovery increase

Index UDK: 532.5; 622.276

Keywords: reservoir management, oil recovery factor, production enhancement operations, maintenance of reservoir pressure, horizontal well completions, hydraulic fracturing and spontaneous fracturing, multi-stage hydraulic fracturing, well logging in open hole and cased hole, well-testing, permanent downhole gages, databases, automated workstations

Bibliography:
1.RD 153-39.0-109-01. Methodical instructions on the integration and the stages of the performance of production logging, well-testing and geochemical survey of oil and oil and gas fields. Moscow, 2002 (in Russian).
2.Kremeneckij M.I., Ipatov A.I., Gulyaev D.N. Informacionnoe obespechenie i tekhnologii gidrodinamicheskogo modelirovaniya neftyanyh i gazovyh zalezhej [Informational and technological support of dynamic reservoir modeling of oil and gas fields]. M.-Izhevsk, 2011, 896 p.
3.Ipatov A.I., Kremeneckij M.I. Long-term monitoring of reservoir parameters as a progressive trend of modern well-testing. Inzhenernaya praktika [Engineering practice], 2012, no. 9, p. 4-8 (in Russian).
4.Adiev A.R., Laptev V.V., Ipatov A.I. i dr. Development of well logging technologies in the process of hydrocarbon production for monitoring of commingled layers. Karotazhnik [The well-log analyst], 2014, no. 2, p. 48-59 (in Russian).
5.Martynov V.G., Ipatov A.I., Kremenetskiy M.I., Gulyaev D.N., Krichevskiy V.M., Kokuri- na V.V., Melnikov S.I. Permanent reservoir monitoring by logging gages at the stage of tight oil reco- very. Neftyanoe hozyajstvo [Oil Industry], 2014, no. 3, p. 106-109 (in Russian).
6.Gulyaev D.N., Kokurina V.V., Kremenetskiy M.I., Krichevskij V.N., Mel’nikov S.I. Wells interference determination by permanent down-hole monitoring on base of sector modeling. Neftyanoe hozyajstvo [Oil Industry], 2012, no. 12, p. 82-85 (in Russian).
7.Mel’nikov S.I. A new way to determine permeability, skin-factors and formation pressures of comingled reservoirs based on reservoir surveillance. Inzhenernaya praktika [Engineering practice], 2012, no. 2, p. 38-43 (in Russian).
8.Morozovskij N.A., Kremeneckij M.I. New Well-test interpretation method for carbonate reservoirs with rare long fractures for field development optimization. Tezisy doklada X Vserossiyskoy naychno-tehnichesskoy konferencii «Aktual’nue problemy razvitiya neftegazovogo komplexa Rossii [Abstracts of the X all — Russian Scientific and technical conference «Actual problems of development of oil and gas complex of Russia»]. Moscow, 2014, p. 16-17.
9.Ipatov A.I., Kremeneckij M.I., Kaeshkov I.S., Klishin I.A., Solodyankin M.A., Figura E.V. Undiscovered DTS potential of horizontal well inflow profile monitoring Neftyanoe hozyajstvo [Oil Industry], 2014, no. 5, p. 96-100 (in Russian).

2018/3
Identifying parameters of porosity change in complex reservoir after clay acid treatment
Geosciences

Authors: Alexander V. LOBUSEV graduated from Gubkin Moscow Institute of petrochemical and Gas Industry in 1980, from the Geological Faculty. Professor, Doctor of Geological and Mineralogical Sciences of Gubkin Russian State University of Oil and Gas (National Research University). He is the author of more than 130 scientific publications. E-mail: lobusev@gmail.com
Olga V. TYUKAVKINA she graduated from Tomsk State University in 1997, with a degree in Geological Survey, Prospecting and Exploration. Associate Professor, Candidate of Geological and Mineralogical Sciences of Gubkin Russian State University of Oil and Gas (National Research University). She is the author of more than 70 scientific publications. E-mail: kpgng@gubkin.ru
Irina S. PERMYAKOVA, reservoir Engineer, CGG Vostok. She is the author of 2 scientific publications. E-mail: kpgng@gubkin.ru
Nikolay V. MILETENKO, deputy Director of the Department of State Policy and Regulation in the Field of Geology and Subsoil Use of the Ministry of Natural Resources of the Russian Federation. Doctor of Geological and Mineralogical Sciences, Professor.
E-mail: minprirody@mnr.gov.ru
Alexander P. POZDNYAKOV graduated from Gubkin Moscow Institute of petrochemical and Gas Industry in 1978, from the specialty Applied Mathematics, he have finished a postgraduate study in 1981, in 2004, doctoral studies there. Professor, Doctor of Technical Science of Gubkin Russian State University of Oil and Gas (National Research University). He is the author of more than 100 scientific works and inventions, more than 10 teaching and methodical works, one monograph. E-mail: kpgng@gubkin.ru

Abstract: Currently, the deposits located within the Fedorov dome structure are at the final stage of development. The share of complex projects under construction containing difficult-to-recover reserves is more than 98 %. All reservoirs are characte- rized by low natural permeability, high clay content, significant water retention ability and heterogeneity in mineralogical composition and reservoir properties. It is important to note that the heterogeneity of rocks in the content of carbonates is generally low and medium, while a complexly built reservoir often contains interlayers with a high content of carbonates. In such conditions, deposits are developed using the technology of clay acid system treatment (aqueous clay-acid compounds with boric acid additives) without prior removal of carbonate compounds

Index UDK: 550.832

Keywords: hydrochloric acid solution, clay-acid solution, surface-active substances, inhibitor, stabilizer, porosity

Bibliography:
1. Bulatov A.I., Kachmar Yu.D., Makarenko P.P., Yaremiychuk R.S. Well development. Refe- rence manual. M., Nedra, 1999, 467 p.
2. Kalinin V.F. Lithological and physical criteria for optimization of the technology of clay-acid treatment of terrigenous reservoirs. Proceedings of the Saratov University, series of Sciences about the Earth, issue 1, vol. 7, 2007, p. 67-74.
3. Lobusev A.V., Strakhov P.N., Lobusev M.A. A new approach to assessing and predicting the productivity of oil and gas saturated rocks. Academic Journal of Western Siberia, 2014, vol. 10, no. 2, p. 45-46.
4. Tyukavkina O.V. Construction of lithological and filtration-capacitive models of complex reservoirs (on the example of the Surgut arch deposits) Bulletin of Voronezh State University. Series: Geology, 2015, no. 1, p. 41-48.

2018/3
Weathering crust of basement of southern part of Nepsko-Botuobinskaya anticline for prospective exploration for oil and gas
Geosciences

Authors: Alexander V. POSTNIKOV, head of Department of Lithology of Gubkin Russian State University of Oil and Gas (National Research University). Doctor of Geological and Mineralogical Sciences. In 1971, he graduated from Gubkin University, specializing in Geology and Exploration of Oil and Gas Fields. Received candidate’s degree in 1976. Research interests: lithology of oil and gas deposits, tectonics of platform oil and gas provinces, Precambrian Geology. Author and co-author of more than 150 published works, including 4 monographs, on various problems of Geology. E-mail: postnikov.a@gubkin.ru
Olga V. POSTNIKOVA, doctor of Geological and Mineralogical Sciences, Professor (since 2009), Head of the Research Laboratory on Oil and Gas Potential of Eastern Siberia (since 2001) of Gubkin Russian State University of Oil and Gas (National Research University). In 1979 she graduated from Gubkin University, specializing in «Geology and exploration of oil and gas fields». Received candidate’s degree in 1976. Research interests: lithology of oil and gas deposits, carbonate reservoirs, geology of Eastern Siberia. Author of more than 70 scientific papers and textbooks. E-mail: olgapostnikova@yandex.ru
Ilnur A. SABIROV, post-graduate student of the Lithology Department from 2017. He Master’s degree in «Oil and gas business» in 2017. Area of scientific interests: fractured reservoir, fault-block structure, complex manifold, basement rocks, the void space of reservoir rocks. Author and co-author of 15 scientific papers. E-mail: sabirov.i@gubkin.ru
Yuliana V. ROSTOVTSEVA, doctor of geological and mineralogical Sciences since 2012, head of the Department of oil and gas sedimentology and marine Geology. Аuthor of 140 scientific works, including 8 collective textbooks and monographs. Area of scientific inte- rests — identification of regularities of sedimentogenesis and lithogenesis, conducting paleogeographic reconstructions with the definition of the facial structure of the strata, the recovery of the history of the development of sedimentation basins, geochronological studies on the calculations of astronomical cycles. E-mail: rostovtseva@list.ru

Abstract: This article is about the structure and composition of the weathering crust of the basement of the southern part of the Nepsko-Botuobinskaya anticline. The authors classified and named the rocks composing the upper part of the crystalline basement according to the 3rd edition of the latest Petrographic Code of Russia, published in 2008. In addition, reservoir properties of weathered rock were estimated. The question about weathering rocks as a prospect for oil and gas exploration was discussed

Index UDK: 552.086; 550.8.011

Keywords: weathering crust, basement, prospect, nomenclature, classification, reservoir rocks

Bibliography:
1. Goryunov E.Yu., Ignatov p.A., Trofimov V.A., Sabirov I.A. Perspectivi neftegazonosnosty fundamenta Jigulyovskogo vala. Geologya nefti i gaza, 2017, no. 2.
2. Konovaltseva E.S., Postnikova O.V., Postnikov A.V., Toporkov V.G., Savchenko S.I. Vtorichnie processi v porodah-kollektorah yaraktinskogo gorizonta yugo-vostochnogo sklona Nepsko-Botuobinskoy anteklizi/ Litologiya i poleznyt iskopaemie, 2011, no. 5, p. 505-509.
3. Kucheruk E.V. Neftegozonosnost porod fundamenta. Geology nefti i gaza, 1992, no. 1, p. 45-46.
4. Petrographic code of Russia (ed. 3). S-Pb., Izd-vo VSEGEI, 2009, 200 р.
5. Pospelov V.V. Kristallicheskiy fundament: geologo-geofizicheskie metodi izucheniya kollektorskogo petenciala I neftegazonosnosti. M.-Izhevsk, Institute of computer science, Scientific Publishing Center «Regular and chaotic dynamics», 2005, 260 p.
6. Postnikov A.V., Muslimov R.H., Plotnikova I.N. K voprosu o roli endogennogo factora v formorovanii i raspredelenii neftegazonosnosti osadochnih basseinov (na primere Tatarstana). Georesursi, 2005, no. 1 (16), p. 37-39.
7. Trofimov V.A. Glubinnie regionalnie siysmorazvedochnie issledovaniya MOGT neftegazonosnih territoriy. M.: GEOS, 2014, 202 p.
8. Trofimov V.A. Ocenka vozmozhnosti prognozirovaniya razuplotnennih zon kristallicheskogo fundamenta po seysmicheskim dannim. Geologo-geofizicheskoe modelirovanie pri poiskah nefti i gaza. M.: Igirgi, 1991, p. 126-133.
9. Trofimov V.A., Goryunov E.Y., Sabirov I.A. Innovacionnie podhodi k resheniyu problemi poiskov uglevodorodov v glubokozalegayushih gorizontah Volgo-Uralskoy neftegazodobivayushey provincii. Georesursi, 2017, no 1, p. 59-68.

2018/3
Prospects of using downhole georadar for geonavigation while drilling oil and gas wells
Geosciences

Authors: Valentin V. STRELCHENKO graduated from the Moscow Institute of Petrochemical and Gas Industry named after Academician I.M. Gubkina in 1962. Professor of the Department of Geophysical Information Systems of the Russian State University of Oil and Gas (National Research University) named after I.M. Gubkina, Doctor of Technical Sciences Research interests: seismic survey integration, GIS and GTI for oil and gas exploration on the shelf, well drilling research, methane extraction from coal beds, tomographic petrophysics. The author and co-author of over two hundred published works, among them 5 monographs, textbooks and tutorials, 48 copyright inventions and patents. E-mail: strelvv@gmail.com
Ivan V. KUZNETSOV graduated from the Geological Faculty of SSU N.G. Chernyshevsky, specialty «Geology of oil and gas» in 2000. Deputy Director General for Geological and Technological Support of NPO CISS LLC. Research interests: control and optimization of technological processes of well construction, including geophysical research of wells, geological and technological research, remote monitoring, optimization of the trajectory of directional wells. Author and co-author of more than ten published works on relevant topics. E-mail: kuznetsov@nposngs.ru
Ilya S. KOZHEVNIKOV graduated from the Faculty of Physics of the Saratov State University named after V.G. Chernyshevsky in 2009. General Director of NPF Geoscan LLC. Research interests: geological and technological research of wells and well logging in the drilling process, automation of recognition of technological operations, optimization of technological processes of well construction. Author and co-author of five published works of the relevant topics. E-mail: S.Kozhevnikov@gazpromgeofizika.ru
Victor Y. CHIRKOV graduated from the Faculty of Physics of the Saratov State University named after VG Chernyshevsky in 2006. Leading Specialist LLC NPF «Geoscan». Research interests: geological and technological research of wells and GIS in the drilling process, the development of equipment for monitoring technological processes of well construction, conducting geophysical and geological and geochemical studies. Author and co-author of more than ten published works on relevant topics.
E-mail: vychirkov@sngs-geo.ru

Abstract: The analysis of the current state of exploration of the geological environment by borehole georadars is made on the basis of which the prospects for using the available modern technical solutions and techniques for processing and interpreting the information are given. These are adaptated to oil and gas fields during well construction. The main physico-geological models of productive layers, characteristic for the geological structure of gas, gas-condensate and oil deposits, are considered. In the process of work, modeling was used, including the use of special physical models. Based on the results of the research, conclusions were drawn about the most optimal way of development and introduction of a new technology, i.e. the creation of an instrumentation and methodological complex for geonavigation of well bores using georadars

Index UDK: 622.276.031:532.11 (571.56)

Keywords: georadiolocation, geonavigation, horizontal wells, GIS, GIS-drilling, water-oil contact, gas-water contact

Bibliography:
1. Shtun’ S.Yu., Rakitin M.V. Mozhno li obognat’ zarubezhnye kompanii v oblasti GIS-bureniya (MWD&LWD)? Burenie i neft’, 2016, no. 10, p. 16-20.
2. Gorbachev Yu.N. Geofizicheskie issledovaniya skvazhin. M.: Nedra, 1990, 398 p.
3. Epov M.I., Glinskikh V.N. Elektromagnitnyy karotazh: modelirovanie i inversiya. Novosibirsk: Akademicheskoe izdatel’stvo «Geo», 2005, 100 p.
4. Kozhevnikov S.V., Duzin V.I. Kazhdomu tipu modeli — svoy klass karotazha. Nefteservis. 2008, no. 1 (8), p. 52-54.
5. Finkel’shteyn M.I., Kutev V.A., Zolotarev V.P. Primenenie radiolokatsionnogo podpoverkhnostnogo zondirovaniya v inzhenernoy geologii. M.: Nedra, 1986, 128 p.
6. Vladov M.L., Starovoytov A.V. Vvedenie v georadiolokatsiyu [Tekst]: Uchebnoe posobie — M.: Izdatel’stvo MGU, 2004, 153 p.
7. Kutev V., Karpukhin V., Finkel’shteyn M. Podpoverkhnostnaya radiolokatsiya. M.: Radio i Svyaz’, 1994, 216 p.
8. Voprosy podpoverkhnostnoy radiolokatsii/pod red. A.Yu. Grineva. M.: Radiotekhnika, 2005, 416 p.
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10. Popov S.B., Yarmakhov I.G. Matematicheskoe modelirovanie pri zondirovanii okoloskvazhinnogo prostranstva priborami so sverkhkorotkimi elektromagnitnymi impul’sami//Preprinty IPM im. M.V. Keldysha, 2013, no. 10, 32 p. URL:http://library.keldysh.ru/preprint.asp?id=2013-10 (data obrashcheniya 25.02.2015)
11. Epov M.I., Savin I.V., Mironov V.L. Spektroskopicheskie kharakteristiki dielektricheskoy pronitsaemosti vlazhnykh gornykh porod//Materialy XII Mezhdunar. nauch. konf. «Reshetnevskie chteniya» (Krasnoyarsk, 10-12 noyabrya 2008 g.), p. 116-117.
12. Epov M.I., Mironov V.L., Bobrov P.P., Savin I.V., Repin A.V. Issledovanie dielektricheskoy pronitsaemosti neftesoderzhashchikh porod v diapazone chastot 0,05-16 GGts. Geologiya i geofizika, 2009, vol. 50, no. 5, p. 630-647.
13. Frequency Spectrum Change of Borehole Radar Signals and Blind Separation. S. Ebihara, M. Kiso. Proceedings of the Tenth International Conference on Ground Penetrating Radar. Delft, The Netherlands, 21-24 June, 2004, p. 257-260.
14. Hue Y.-K., Teixeira F.L., San Martin L.E., Bittar M. Modelling of EM Logging Tools in Arbitrary 3-D Borehole Geometries Using PML-FDTD. IEEE Transaction on Geoscience and Remote Sensing, 2005, vol. 2, no. 1, p. 78-81.
15. Ebihara S., Hashimoto Y. MoM Analysis of Dipole Antennas in Crosshole Borehole Radar and Field Experiments. IEEE Transactions on Geoscience and Remote Sensing, 2007, no. 10, p. 2435-2450.
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23. Ebihara S. Directional Borehole Radar With Dipole Antenna Array Using Optical Modulators. IEEE Transactions on Geoscience and Remote Sensing, 2004, vol. 42, no. 1, p. 45-58.
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2018/3
Accounting for influence of asymmetry of horizontal wells placement along reservoir to plan number of wellsto be drilled
Geosciences

Authors: Zagid S. ALIEV graduated from Azibekov Azerbaijani industrial Institute in 1957. He is Professor of the Department of Gas and Condensate Field Development and Operation of Gubkin Russian State University of Oil and Gas (National Research University). He has been head and the executive director of projects of development of oil and gas fields of Russia, Iran, Iraq, Vietnam, Kazakhstan, Algeria, Germany, etc., and also author of normative documents of OAO Gazprom such as instructions, manuals and standards of enterprises. He is author of 365 publications, including 35 monographs and 30 thematic brochures.
E-mail: rgkm@gubkin.ru
Elena M. KOTLYAROVA graduated from Gubkin Russian State University of Oil and Gas in 1988. She is Candidate of Technical Sciences, associate professor of the Dept. of Gas and Condensate Field Development and Operation of Gubkin Russian State University of Oil and Gas (National Research University). She is expert in the field of development and operation of gas and gas-condensate fields and UGS. She is author of 50 publications. E-mail: kotlyarova_gubkin@mail.ru

Abstract: We have analyzed the effect of asymmetry of the horizontal wellbore placement along the reservoir. Studies of the location of horizontal wells have shown that the performance of such wells will vary significantly with the thickness of the reservoir, as this is predetermined by increased distance from the horizontal wellbore. The authors carried out the necessary gas-hydrodynamic calculations to use these to design the development of gas and gas condensate fields with different capacitive filtration properties. The results of these calculations are given in the article in tabular and graphical forms, which can be used in practical calculations to determine the number of horizontal wells to be drilled, taking into account the asymmetric placement of such wells in the reservoir thickness

Index UDK: 622.276

Keywords: asymmetry of placement, horizontal well, productivity of horizontal wells, thickness of reservoir, coefficients of filtration resistance, underbalance, symmetric arrangement

Bibliography:
1. Aliev Z.S., Sheremet V.V. Opredelenie proizvoditel’nosti gorizontal’nyh skvazhin, vskryvshih gazovye i gazoneftyanye plasty. M.: Nedra, 1995, 131 p.
2. Aliev Z.S. i dr. Teoreticheskie i tekhnologicheskie osnovy primeneniya gorizontal’nyh skvazhin dlya osvoeniya gazovyh i gazokondensatnyh mestorozhdenij. M.: Nedra, 2014, 231 p.
3. Aliev Z.S. Vliyanie razlichnyh faktorov na debit gorizontal’nyh skvazhin. NTZH Tekhnologiya TEHK, 2007, iyun’.
4. Aliev Z.S., Kotlyarova E.M. Vliyanie razmeshcheniya po ploshchadi, profilya i polnoty vskrytiya gazonosnyh plastov na proizvoditel’nost’ gorizontal’nyh skvazhin. Metodicheskoe posobie. Orenburg, Tipografiya IP SHCHerbakov, 2010, 92 p.
5. Aliev Z.S., Kotlyarova E.M. Opredelenie proizvoditel’nosti gorizontal’noj skvazhiny, vskryvshej plast s peremennoj tolshchinoj. Trudy VI Mezhdunarodnogo tekhnologicheskogo simpo-ziuma. M.: Institut neftegazovogo biznesa, 2007.
6. Aliev Z.S., Rebrikov A.A. Priblizhennyj metod poiska optimal’nyh razmerov fragmenta pryamougol’noj formy i ego vskrytiya dlya obespecheniya maksimal’nogo debita gorizontal’noj skvazhiny. Burenie i neft’, 2007, no. 2.

2018/3
Сalculation of anti-icing system of heat-exchange section for integrated air-cleaning system of gas turbine engine
Geosciences

Authors: Bogdan V. BUDZULYAK graduated from Ivano-Frankovsk University of Oil and Gas in 1970 and from Russian Presidential Academy of National Economy in 1995. Doctor of Technical Sciences, President of the Self-Regulatory Organization «Association of costructors of gas and oil complexes», Professor of the Department of Construction and Repair of Gas and Oil Pipelines and Storage Facilities of Gubkin Russian State University of Oil and Gas (National Research University), member (academician) of the Academy of Mining Sciences. He is author of more than 100 scientific publications. E-mail: ebaruk@asgink.ru
Alexander F. KALININ graduated from Gubkin Moscow Institute of Oil and Gas Industry in 1976. Doctor of Technical Sciences, Professor of the Department of Thermo-dynamics and Heat engines of Gubkin Russian State University of Oil and Gas (National Research University). He is author of more than 110 scientific publications. E-mail: kalinine.a@gubkin.ru
Artem Y. FEDOSEEV graduated from Bauman Moscow State Technical University in 2012. He is currently working on his thesis for Candidate of Technical Sciences of the Department of Thermodynamics and Heat Engines of Gubkin Russian State University of Oil and Gas (National Research University) He is author of 10 scientific publications. E-mail: artemyfed@yandex.ru

Abstract: Protection of the inlet air-cleaning system of the gas turbine engine from ice formation is an important aspect of the operation of the gas-compressor unit during the autumn-winter operation period. The article presents a comparative analysis of the existing methods for the implementation of anti-icing systems, describes their advantages and disadvantages. A method for thermal and hydraulic calculations of a modernized anti-icing system using a heat-exchange section is presented. Gas pumping unit GPA-C-16 is used as an example for the calculation and design sketching

Index UDK: 621.45.03

Keywords: gas turbine engine, air-cleaning system, anti-icing system, thermal design, heat-exchange section

Bibliography:
1. Vanchin A.G., Romonenkov S.V., Fedoseev A.Y. Anti-icing system for air inlet system of gas compressor unit with gas turbine engine. Patent RF, 2017, no. 174364.
2. Gavra G.G., Mihailov P.M., Ris V.V. Thermal and hydraulic calculation of heat exchangers for compressor plants. Leningrad, 1982, 72 p.
3. State Standard 8732-78. Seamless hot-deformed steel pipes. Range of sizes. Moscow, Standinform Publ., 1979, 9 p. (in Russian).
4. Idelchik I.E. Reference book on hydraulic resistance. Moscow, Mashinostroenie, 1992, 672 p.
5. Ponkin V.N., Giltcov E.I., Kesel B.A., Kornoukhov A.A. The set of technical solutions to increase the efficiency of gas compressor units. Gas turbine technology, 2009, no 2, p. 18–22.
6. Company Standard STO Gazprom 2-2.1-226-2008. Technical requirements for air inlet system for gas compressor units. Moscow, Gazprom Publ., 2008, 22 p. (in Russian).
7. Kalinin A.F., Kupcov S.M., Lopatin A.S., Shotidi K.H Theoretical foundations of heat engineering. Thermodynamics and heat transfer in the technological processes of the oil and gas industry. Moscow, Gubkin Russian State University of Oil and Gas, 2016, 348 p.
8. Troshin A.K., Kupcov S.M., Kalinin A.F. Thermodynamic and thermophysical properties of working bodies of thermal power plants. Moscow, MPA-Press, 2006, 78 p.
9. Fedoseev A.Y. Increase of efficiency of anti-icing system of air inlet system of GPA-C-16. Gas turbine technology, 2017, no. 5, p. 22-26.
10. Schroth T. Customized filter concepts for intake air filtration in gas turbines and turbocom-pressors. Diesel & Gas Turbine Worldwide, October 1993, p. 38-40.

2018/3
The update of topographical plans in order to bring the information displayed on them in accordance with the current state of the area and construction in engineering surveys for construction
Geosciences

Authors: Tatiana N. KOVALEVA graduated from the N.I. Vavilov Saratov State Agrarian University in 2003. She is Candidate of Economic Sciences, Associate Professor of the Department of Construction and Repair of Gas and Oil Pipelines and Storage Facilities of Gubkin Russian State University of Oil and Gas (National Research University). She is specialist in the field of land management, cadaster, land reclamation, recultivation, monitoring, protection of land, geodesy and geoinformatics, valuation of land and real estate. She is author of more than 90 scientific and methodical works. E-mail: tnk2003@list.ru
Alexander N. KOVALEV graduated from the N.I. Vavilov Saratov State Agrarian University in 2000. He is Candidate of Technical Sciences, chief specialist of the Department of Construction Solutions and Engineering Support of the Saratov Branch of FAI «Glavgosexpertiza of Russia». He is specialist in the field of land management, cadaster, land reclamation, recultivation, monitoring, protection of land, geodesy and geoinformatics, valuation of land and real estate. He is author of more than 20 scientific and methodical works. E-mail: tnk2003@list.ru
Sergei I. SENTSOV graduated from Gubkin Russian State University of Oil and Gas in 1978, he is Doctor of Technical Sciences, Professor of the Department of Construction and Repair of Gas and Oil Pipelines and Storage Facilities of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of construction of gas and oil pipelines and storage facilities. He is author of over 70 scientific and educational-methodical works. E-mail: srgnp@mail.ru

Abstract: At present, often enough during engineering and geodetic surveys previously created engineering and topographic plans are updated to the current state of the terrain and buildings. The update may be required when using as initial the survey data obtained at the previous stages of urban development, if more than two years have elapsed since the survey, during surveys in the winter with snow depth over 20 cm, with changes in the terrain of more than 35%, or when the survey is conducted in two stages. Despite the apparent simplicity, in the pro-cess of this type of work techniques and technologies that areprescribed by regulatory documents are violated. The authors consider the issues of compli-ance with the requirements of technical regulations and sets of rules when updating engineering and topographic plans. Recommendations are given for improving the procedure for the accumulation of archives of engineering survey data and state supervision of their use

Index UDK: 528.2/5; 528.42

Keywords: engineering surveys, engineering and geodetic surveys, topographic plans, maps, cartographic material, geodesy, project documentation, construc-tion, reconstruction, major repairs, territory planning, architectural and construc-tion design, capital construction projects, laps of limitation, adjustment, update, change of situation, terrain, territory, scale, data archives, research program, aging index, deformation rate of plans and maps

Bibliography:
1. Gradostroitel’nyj kodeks Rossijskoj Federacii (Feder. zakon prinyat Gos. Dumoj 29 dekabrya 2004 g. po sostoyaniyu na 30 iyulya 2018 g.) [Elektronnyj resurs]. Rezhim dostupa: http:// www.consultant.ru
2. Postanovlenie Pravitel’stva Rossijskoj Federacii «Ob inzhenernyx izyskaniyax dlya podgotovki proektnoj dokumentacii, stroitel’stva, rekonstrukcii ob’ektov kapital’nogo stroitel’stva» (vmeste s «Polozheniem o vypolnenii inzhenernyx izyskanij dlya podgotovki proektnoj dokumentacii, stroitel’stva, rekonstrukcii obektov kapital’nogo stroitel’stva») ot 19.01.2006 Nо. 20 po sostoyaniyu na 30 iyulya 2018 g. [Elektronnyj resurs]. Rezhim dostupa: http://www.consultant.ru
3. Postanovlenie Pravitel’stvo Rossijskoj Federacii "Ob ustanovlenii trebovanij k periodichnosti obnovleniya gosudarstvennyx topograficheskix kart i gosudarstvennyx topograficheskix planov, a takzhe masshtabov, v kotoryx oni sozdayutsya ot 12 noyabrya 2016 g. Nо. 1174 po sostoyaniyu na 30 iyulya 2018 g. [Elektronnyj resurs]. Rezhim dostupa: http://www.consultant.ru
4. Prikaz Minekonomrazvitiya Rossii "Ob utverzhdenii poryadka peredachi federal’nymi orga-nami ispolnitel’noj vlasti materialov i dannyx dlya vklyucheniya v federal’nyj, territorial’nye i vedomstvennye kartografo-geodezicheskie fondy, poryadka podachi zayavlenij o predostavlenii v pol’zovanie materialov i dannyx iz federal’nogo, territorial’nyx i vedomstvennyx kartografo-geodezicheskix fon-dov, formy zayavleniya o predostavlenii v pol’zovanie materialov i dannyx iz federal’nogo, territorial’nyx i vedomstvennyx kartografo-geodezicheskix fondov i sostava prilagaemyx k nemu dokumentov, poryadka i formy predostavleniya materialov i dannyx iz federal’nogo, territorial’nyx, vedomstvennyx kartografo-geodezicheskix fondov, perechnya materialov i dannyx, podlezhashhix vklyucheniyu v federal’nyj kartografo-geodezicheskij fond" ot 02.12.2011 No. 706 po sostoyaniyu na 30 iyulya 2018 g. [Elektronnyj resurs]. Rezhim dostupa: http://www.consultant.ru
5. SP 47.13330.2016. Svod pravil. Inzhenernye izyskaniya dlya stroitel’stva. Osnovnye polo-zheniya. Aktualizirovannaya redakciya SNiP 11-02-96 (utv. i vveden v dejstvie Prikazom Minstroya Rossii ot 30.12.2016 Nо. 1033/pr) [Elektronnyj resurs]. Rezhim dostupa: http://www.cntd.ru
6. SP 11-104-97. Inzhenerno-geodezicheskie izy`skaniya dlya stroitel’stva (odobren Pis’mom Gosstroya RF ot 14.10.1997 N 9-4/116) [Elektronnyj resurs]. Rezhim dostupa: http://www.cntd.ru
7. Spravochnik bazovyx cen na inzhenernye izyskaniya dlya stroitel’stva. Inzhenerno-geode-zicheskie izyskaniya (Utverzhden i vveden v dejstvie Postanovleniem Gosstroya RF ot 23 dekabrya 2003 g. N 213). [Elektronnyj resurs]. Rezhim dostupa: http://www.cntd.ru
8. GKINP-02-127-80. Rukovodstvo po redaktirovaniyu topograficheskix krupnomasshtabnyx kart i planov (utv. Prikazom GUGK SSSR ot 07.04.1980 No. 118p) [Elektronnyj resurs]. Rezhim dostupa: http://www.cntd.ru
9. GKINP-02-033-82. Instrukciya po topograficheskoj s’emke v masshtabax 1:5000, 1:2000, 1:1000 i 1:500 [Elektronnyj resurs]. Rezhim dostupa: http://www.cntd.ru
10. Avdeev Yu.M., Popov Yu.P. Primenenie geoinformacionnyx sistem v stroitel’stve. No-vaUm.Ru, 2018, no. 12, p. 260-264.
11. Blyumin N.A. Uskorennye metody obnovleniya topograficheskix kart s ispol’zovaniem prozrachnyx plastikov. Izvestiya vuzov, Geodeziya i aerofotos’emka, 1967, no. 4.
12. Vasil’ev G.G., Kovaleva T.N. Zemleustroitel’noe obespechenie proektirovaniya, stroitel’stva, rekonstrukcii i ekspluatacii ob’ektov neftegazovogo kompleksa. Trudy Rossijskogo gosudarstvennogo universiteta nefti i gaza imeni I.M. Gubkina, 2014, no. 2 (275), p. 103-117.
13. Vasil’ev G.G., Kovaleva T.N. Strategicheskoe i territorial’noe planirovanie pri realizacii proektov stroitel’stva i rekonstrukcii ob’ektov truboprovodnogo transporta v Rossijskoj Federacii. Gazovaya promyshlennost’, 2017, no. 7 (755), p. 42-49.
14. Vershinin V.V., Kovaleva T.N. Zemleustroitel’noe obespechenie rabot po rezervirovaniyu zemel’ dlya gosudarstvennyx i municipal’nyx nuzhd. Mezhdunarodnyj sel’skoxozyajstvennyj zhurnal, 2013, no. 5-6, p. 65-68.
15. Vol’pe R.I. Ispol’zovanie materialov kartograficheskogo znacheniya pri sozdanii i redak-tirovanii topograficheskix kart. Trudy CzNIIGAiK, 1962, vol. 155.
16. Galkin V.M. Texnologiya sostavleniya sostavitel’skix i izdatel’skix originalov pri obnovlenii kart. Texnologiya odnovremennogo obnovleniya topograficheskix kart vsego masshtabnogo ryada. M.: GUGK, 1973.
17. Goldman L.M., Vol’pe R.I. Deshifrirovanie aerosnimkov pri topograficheskoj s’emke i obnovlenii kart masshtabov 1:10 000 i 1:25 000. Trudy CzNIIGAiK, 1968, vol. 185.
18. Emel’yanov K.S., Korshunov A.P., Fedorkova Yu.V. Obnovlenie topograficheskix kart s pomoshhyu rossijskix sputnikovyx dannyx. Zemel’nyj vestnik Moskovskoj oblasti, 2010, no. 5.
19. Kovaleva T.N. Dokumentaciya po planirovke territorii kak osnova svoevremennoj realizacii ob’ektov social’no ekonomicheskogo razvitiya territorij. Agroforsajt, 2016, no. 5 (5), p. 5.
20. Kovalev A.N. Obnovlenie inzhenerno-topograficheskix planov. Vestnik Gosudarstvennoj ekspertizy, 2018, no. 1/2018 (6), p. 48-53.
21. Kozhevnikov N.P. K voprosu obnovleniya topograficheskix kart. Geodeziya i kartografiya, 1969, no. 5.

2018/3
Сhecking quality of welded pipes for gas pipelines for compliance with static and dynamic crack resistance normative requirements
Geosciences

Authors: Georgy I. MAKAROV graduated from Bauman Moscow Higher Technical School in 1973. He is Doctor of Technical Sciences, Professor of the Department of Welding and Oil and Gas Facilities Monitoring of Gubkin Russian State University of Oil and Gas (National Research University). He is specialist in the field of strength and fracture mechanics. He is author of more than 100 works, a monograph and a textbook. E-mail: svarka@gubkin.ru

Abstract: The article considers a new system for quality assurance of large diameter welded pipes for main gas pipelines in terms of fracture toughness. We propose to use the existing quality assurance system for tubulars for oil and petroleum products pipeline transport. It is proposed to use static fracture toughness and long crack propagation resistance as the normalized fracture toughness parameters, These have not been previously used for main gas pipelines

Index UDK: 621.791; 624.042; 624.044; 624.046

Keywords: main gas pipeline, welded pipes, quality parameters assurance, fracture toughness, static crack resistance, long crack propagation resistance

Bibliography:
1.Makarov G.I. Protyazhennye razrusheniya magistral’nyh gazoprovodov. Pod red. A.D. Sedyh. M.: Izdatel’stvo «Academia», 2002, 208 p.
2.Makarov G.I., Dimov L.A. Vliyanie gruntovoj zasypki osnovaniya na protyazhennye razrusheniya podzemnyh magistral’nyh gazoprovodov. Osnovaniya, fundamenty i mekhanika gruntov, 2005, no. 2, p. 7-10.
3.Makarov G.I., Dimov L.A. Effect of Soil Backfill of Bed on Extended Failures of Underground Gas Mains. Soil Mechanics and Foundation Engineering, 2005, vol. 42, no. 2, p. 46-50.
4.Makarov G.I. Dopolnenie k teorii rascheta magistral’nyh gazoprovodov na soprotivlyaemost’ protyazhennym razrusheniyam. Truboprovodnyj transport [Teoriya i praktika], 2008, no. 1, p. 22-25.
5.Makarov G.I. Utochnennaya teoreticheskaya model’ deformirovaniya truby magistral’nogo gazoprovoda pri protyazhennom bezostanovochnom razrushenii. Truboprovodnyj transport [Teoriya i praktika], 2008, no. 2, p. 16-19.
6.Makarov G.I. Vliyanie topografii dvizheniya treshchiny na soprotivlyaemost’ magistral’nogo gazoprovoda protyazhennomu bezostanovochno-mu razrusheniyu. Truboprovodnyj transport [Teoriya i praktika], 2009, no. 1, p. 21-23.
7.Makarov G.I. Normativnye trebovaniya po vyazkosti razrusheniya metalla trub magistral’nyh gazoprovodov v otnoshenii ih soprotivlyae-mosti protyazhennym bezostanovochnym razrusheniyam. Truboprovodnyj transport [Teoriya i praktika], 2010, no. 1, p. 17-19.
8.Makarov G.I. Normativnye trebovaniya k vyazkosti razrusheniya trubnyh stalej. Svarochnoe proizvodstvo, 2010, no. 5, p. 36-39.
9.Makarov G.I. K voprosu ucheta vliyaniya prodol’noj sily v teoreticheskoj modeli deformirovaniya truby magistral’nogo gazoprovoda pri protyazhennom bezostanovochnom razrushenii. Truboprovodnyj transport [Teoriya i praktika], 2012, no. 1, p. 48-51.
10. Makarov G.I. Trebovaniya k vyazkosti razrusheniya metalla trub magistral’nyh gazoprovo- dov, garantiruyushchie otsutstvie protyazhennyh bezostanovochnyh razrushenij. Truboprovodnyj transport [Teoriya i praktika], 2013, no. 5, p. 12-16.
11. Makarov G.I. Ekspertnaya ocenka soprotivlyaemosti magistral’nyh gazoprovodov, rabotayushchih na ponizhennyh rezhimah perekachki, rasprostraneniyu protyazhennyh bezostanovochnyh razrushenij. Truboprovodnyj transport [Teoriya i praktika], 2013, no. 6, p. 12-17.
12. Makarov G.I. Sovremennye normativnye trebovaniya po pokazatelyam vyazkosti razrusheniya svarnyh trub bol’shogo diametra dlya magistral’nyh truboprovodov. [Svarka i bezopasnost’]. Trudy II Vserossijskoj nauchno-prakticheskoj konferencii, posvyashchennoj 80-letiyu d.t.n., professora A.P. Ammosova, 10-11 oktyabrya 2017 g. Yakutsk, 2017, p. 48-54.
13. Programma rascheta gazoprovoda na soprotivlyaemost’ protyazhennym razrusheniyam. Svidetel’stvo o gosudarstvennoj registracii programmy dlya EHVM No. 2009614102 ot 3 avgusta 2009 g. G.I. Makarov, pravoobladatel’ OOO «Institut VNIIST».
14. Standart organizacii STO 01297858 0.0095.0-2013. Naturnye ispytaniya trub na razryv s cel’yu opredeleniya vyazkosti razrusheniya. Programma i metodika ispytanij. Razrabotchik: Makarov Geor-gij Ivanovich. M.: VNIIST, 2013, 22 p.
15. Makarov G.I., Glazunov S.P. O primenenii vysokoprochnyh i vysokovyazkih trub povyshennyh kategorij kachestva novogo pokoleniya dlya magistral’nyh truboprovodov. Nauchno-tekhnicheskij i proizvodstvennyj zhurnal neftegazovogo stroitel’stva. «NGS», 2012, no. 1, p. 20-29.
16. Makarov G.I. Strategiya tekhnicheskoj politiki modernizacii sistem truboprovodnogo transporta nefti i gaza. Svarochnoe proizvodstvo, 2013, no. 9, p. 44-48.
17. Makarov G.I. Magistral’nyj put’ dlya magistral’nyh truboprovodov. Perspektivy ispol’zovaniya svarnyh vysokoprochnyh trub. Delovoj zhurnal Neftegaz.RU, 2013, no. 1-2, p. 64-69.
18. Makarov G.I. Modernization of Systems of Pipeline Transport of Gas and Oil. Welding International, 2014, vol. 28, no. 9, p. 744-747.
19. Makarov G.I. Po stupenyam normativnoj ierarhii. Podtverzhdenie sootvetstviya trub bol’sho-go diametra dlya magistral’nyh gazoprovodov normativnym trebovaniyam po pokazatelyam vyazkosti razrusheniya. Delovoj zhurnal Neftegaz.RU, 2014, no. 5, p. 18-22.
20. Makarov G.I. Trubnyj vopros. Normirovanie i tekhnicheskoe regulirovanie kachestva trubnoj produkcii dlya magistral’nyh truboprovodov v usloviyah importozameshcheniya. Delovoj zhurnal Neftegaz.RU, 2015, no. 5, p. 12-17.
21. Makarov G.I. Regulirovanie kachestva trub. Principy razrabotki federal’nyh normativnyh dokumentov, reglamentiruyushchih svojstva trubnoj produkcii dlya magistral’nyh truboprovodov v usloviyah importozameshcheniya. Delovoj zhurnal Neftegaz.RU, 2015, no. 11-12, p. 14-20.
22. Makarov G.I. Strategiya tekhnicheskoj politiki. Strategiya tekhnicheskoj politiki v proektirovanii, stroitel’stve i ehkspluatacii sistem truboprovodnogo transporta nefti i gaza. Delovoj zhurnal Neftegaz.RU, 2016, no. 11-12, p. 20-25.