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Development of methods for predicting hydrate formation in gas storage facilities and measures for their prevention and elimination

Treść / Zawartość
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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Purpose: The purpose of this work is to study the processes of hydrate formation during the operation of wells and underground gas storage facilities. Development of a set of measures aimed at the prediction and timely prevention of hydrate formation in wells and technological equipment of gas storage facilities under different geological and technological conditions. Design/methodology/approach: The prediction of hydrate formation processes was carried out using a neural network that is a software product with weight factors calculated in MATLAB environment and the ability to adapt parameters of the network specified to updated and supplemented input data during its operation. So, within the MATLAB software environment, a software module of a two-layer artificial neural network with a random set of weight factors is created at the first stage. In the second stage, the neural network is trained using experimental field input/output data set, output data. In the third stage, an artificial neural network is used as a means of predicting hydrate formation with the ability to refine weight factors during its operation subject to obtaining additional updated data, as an input set, for modifying the coefficients and, accordingly, improving the algorithm for predicting of an artificial neural network. In the absence of new data for the additional training of an artificial neural network, it is used as a computing tool that, on the basis of input data about the current above-mentioned selected technological parameters of fluid in the pipeline, ensures the output values in the range from 0 to 1 (or from 0 to 100%), that indicates the probability of hydrates formation in the controlled section of the pipeline. Application of such an approach makes it possible to teach; additionally that is, to improve the neural network; therefore this means of predicting hydrate formations objectively increases reliability of results obtained in the process of predicting and functioning of the system. The authors of the work recommend to carry out an integrated approach to ensure clear control over the operation mode of wells and gas collection points. Findings: According to the results of experimental studies, the places of the most likely deposition of hydrates in underground gas storage facilities were identified, in particular, in the inside space of the flowline in places of accumulation of liquid contaminants (lowered pipeline sections) and an adjustable choke of the gas collection point. The available methods used to prevent and eliminate hydrate formation both in wells and at gas field equipment were analyzed. Such an analysis made it possible to put together a list of methods that are most appropriate for the conditions of gas storage facilities in Ukraine. The method of predicting hydrate formation in certain sections of pipelines based on algorithms of artificial neural networks is proposed. The developed methodology based on data on values of temperatures and pressures in certain sections of pipelines allows us to predict the beginning of the hydrate formation process at certain points with high accuracy and take appropriate measures. Research limitations/implications: To increase the efficiency of solving the problem of hydrate formation in gas storage facilities, it is expedient to introduce new approaches to timely predict complications, in particular, the use of neural networks and diverse measures. Practical implications: Implementation of the developed predicting methodology and methods and measures to prevent and eliminate hydrate formation in wells and technological equipment in underground gas storage facilities will increase the operation efficiency of underground gas storage facilities. Originality/value: The use of artificial intelligence to predict hydrate formations in flowlines of wells and technological equipment of underground gas storage facilities is proposed. Using this approach to predict and function the system as a whole ensures high reliability of the results obtained due to adaptation of the system to the specified control conditions.
Rocznik
Strony
25--41
Opis fizyczny
Bibliogr. 33 poz., rys., tab.
Twórcy
  • Branch R&D Institute of Gas Transportation Joint Stock Company “Ukrtransgaz”, 16 Koneva str., Kharkiv, Ukraine
  • Department of Oil and Gas Pipelines and Storage Facilities, Institute of Petroleum Engineering, Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska str., Ivano-Frankivsk, Ukraine
  • Joint Stock Company “Ukrgasvydobuvannya”, 26/28 Kudriavska str., Kyiv, Ukraine
autor
  • Department of Energy Management and Technical Diagnostics, Institute of Architecture, Construction and Power Engineering, Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska str., Ivano-Frankivsk, Ukraine
  • Branch Ukrainian Scientific Research Institute of Natural Gases Joint Stock Company “Ukrgasvydobuvannya”, 20 Himnaziina Naberezhna str., Kharkiv, Ukraine
  • Branch Ukrainian Scientific Research Institute of Natural Gases Joint Stock Company “Ukrgasvydobuvannya”, 20 Himnaziina Naberezhna str., Kharkiv, Ukraine
  • Department of Applied Mathematics, Institute of Information Technologies, Ivano-Frankivsk National Technical University of Oil and Gas, 15 Karpatska str., Ivano-Frankivsk, Ukraine
Bibliografia
  • [1] S. Matkivskyi, Increasing hydrocarbon recovery of Hadiach field by means of CO2 injection as a part of the decarbonization process of the energy sector in Ukraine, Mining of Mineral Deposits 16/1 (2022) 114-120. DOI: https://doi.org/10.33271/mining16.01.114
  • [2] S. Matkivskyi, L. Khaidarova, Increasing the Productivity of Gas Wells in Conditions of High Water Factors, Proceedings of the SPE Eastern Europe Subsurface Conference, Kyiv, Ukraine, 2021, SPE-208564-MS. DOI: https://doi.org/10.2118/208564-MS
  • [3] S. Matkivskyi, O. Burachok, Impact of Reservoir Heterogeneity on the Control of Water Encroachment into Gas-Condensate Reservoirs during CO2 Injection, Management Systems in Production Engineering 30/1 (2022) 62-68. DOI: https://doi.org/10.2478/mspe-2022-0008
  • [4] S. Matkivskyi, O. Kondrat, O. Burachok, Investigation of the influence of the carbon dioxide (CO 2) injection rate on the activity of the water pressure system during gas condensate fields development, E3S Web of Conferences 230 (2021) 01011. DOI: https://doi.org/10.1051/e3sconf/202123001011
  • [5] S. Matkivskyi, O. Kondrat, Studying the influence of the carbon dioxide injection period duration on the gas recovery factor during the gas condensate fields development under water drive, Mining of Mineral Deposits 15/2 (2021) 95-101. DOI: https://doi.org/10.33271/mining15.02.095
  • [6] S. Matkivskyi, O. Kondrat, The influence of nitrogen injection duration at the initial gas-water contact on the gas recovery factor, Eastern-European Journal of Enterprise Technologies1/6(109) (2021) 77-84. DOI: https://doi.org/10.15587/1729-4061.2021.224244
  • [7] Ya.V. Doroshenko, G.М. Kogut, I.V. Rybitskyi, O.S. Tarayevs’kyy, T.Yu. Pyrig, Numerical investigation on erosion wear and strength of main gas pipelines bends, Physics and Chemistry of Solid State 22/3 (2021) 551-560. DOI: https://doi.org/10.15330/pcss.22.3.551-560
  • [8] E.G. Hammerschmidt, Formation of gas hydrates in natural gas transmission lines, Industrial and Engineering Chemistry 26/8 (1934) 851-855. DOI: https://doi.org/10.1021/ie50296a010
  • [9] S.Sh. Byk, Yu.F. Makogon, V.I. Fomina, Gas hydrates, Khimina, Moscow, 1980 (in Russian).
  • [10] V.G. Vasilyev, V.I. Yermakov, I.P. Zhabreyev, Gas and gas and condensate fields. Reference book, Nedra, Moscow, 1983 (in Russian).
  • [11] S.T. Guliyants, G.I. Yegorova, A.A. Aksentiyev, Physico-chemical features of gas hydrates: Study guide, Tyumen State Oil and Gas University, Tyumen, 2010 (in Ukrainian).
  • [12] Yu.F. Makogon, G.A. Sarkisyants, Prevention of hydrate formation while production and transportation of gases, Nedra, Moscow, 1966 (in Russian).
  • [13] Rules of gas and gas and condensate fields development, Nedra, Moscow, 1971 (in Russian).
  • [14] G.A. Zotov, Z.S. Aliyev (eds), Guidelines for comprehensive study of gas and gas condensate formations and wells, Nedra, Moscow, 1980 (in Russian).
  • [15] A.I. Gritsenko, Z.S. Aliyev, O.M. Yermilov, V.V. Remizov, G.A. Zotov. Guidelines for wells research, Nauka, Moscow, 1995 (in Russian).
  • [16] V.I. Dmytrenko I.G. Zezekalo, O.O. Ivankiv; applicant and owner ‒ Ukrainian State Geological Exploration Institute. No. 32436 Patent Ukraine, МПК(2006) Е21В 43/11. Complex inhibitor of hydrate formation and corrosion ОV-07, No. u 2008 01115; application 30.01.2008; published 12.05.2008, Information Letter No. 9.
  • [17] N.N. Nguyen, R. Berger, H.-J. Butt, Premelting-induced agglomeration of hydrates: theoretical analysis and modeling, ACS Applied Materials and Interfaces 12/12 (2020) 14599-14606. DOI: https://doi.org/10.1021/acsami.0c00636
  • [18] B.V. Degtyaryev, E.B. Bukhgalter, Combating hydrates while producing gas wells in the northern regions, Nedra, Moscow, 1976 (in Russian).
  • [19] B.V. Degtyaryev, G.S. Lutoshkin, E.B. Bukhgalter, Combating hydrates while producing gas wells in the regions of the North (practical manual), Nedra, Moscow, 1969 (in Russian).
  • [20] V.S. Boiko, R.M. Kondrat, R.S. Yaremiychuk, Reference book on oil and gas business, Ivano-Frankivsk National Technical University of Oil and Gas, Lviv, 1996 (in Ukrainian).
  • [21] Yu.P. Korotayev, R.D. Margulov (eds), Production, treatment and transportation of natural gas and condensate: Reference guide in 2 volumes, Volume I, Nedra, Moscow, 1984 (in Russian).
  • [22] V.B. Volovetskyi, Ya.V. Doroshenko, A.O. Bugai, G.M. Kogut, P.M. Raiter, Y.M. Femiak, R.V. Bondarenko, Developing measures to eliminate of hydrate formation in underground gas storages, Journal of Achievements in Materials and Manufacturing Engineering 111/2 (2022) 64-77. DOI: https://doi.org/10.5604/01.3001.0015.9996
  • [23] V.B. Volovetskyi, Ya.V. Doroshenko, G.M. Kogut, A.P. Dzhus, I.V. Rybitskyi, J.I. Doroshenko, O.M. Shchyrba, Investigation of gas gathering pipelines operation efficiency and selection of improvement methods, Journal of Achievements in Materials and Manufacturing Engineering 107/2 (2021) 59-74. DOI: https://doi.org/10.5604/01.3001.0015.3585
  • [24] V.B. Volovetskyi, A.V. Uhrynovskyi, Ya.V. Doroshenko, O.M. Shchyrba, Yu.S. Stakhmych, Developing a set of measures to provide maximum hydraulic efficiency of gas gathering pipelines, Journal of Achievements in Materials and Manufacturing Engineering 101/1 (2020) 27-41. DOI: https://doi.org/10.5604/01.3001.0014.4088
  • [25] V.B. Volovetskyi, Ya.V. Doroshenko, G.M. Kogut, I.V. Rybitskyi, J.I. Doroshenko, O.M. Shchyrba, Developing a complex of measures for liquid removal from gas condensate wells and flowlines using surfactants, Archives of Materials Science and Engineering 108/1 (2021) 24-41. DOI: https://doi.org/10.5604/01.3001.0015.0250
  • [26] V.B. Volovetskyi, Ya.V. Doroshenko, S.M. Stetsiuk, S.V. Matkivskyi, O.M. Shchyrba, Y.M. Femiak, G.M. Kogut, Development of foam-breaking measures after removing liquid contamination from wells and flowlines by using surface-active substances, Journal of Achievements in Materials and Manufacturing Engineering 114/2 (2022) 67-80. DOI: https://doi.org/10.5604/01.3001.0016.2157
  • [27] V.B. Volovetskyi, Ya.V. Doroshenko, O.S. Tarayevs’kyy, O.M. Shchyrba, J.I. Doroshenko, Yu.S. Stakhmych, Experimental effectiveness studies of the technology for cleaning the inner cavity of gas gathering pipelines, Journal of Achievements in Materials and Manufacturing Engineering 105/2 (2021) 61-77. DOI: https://doi.org/10.5604/01.3001.0015.0518
  • [28] V. Volovetskyi, Ya. Doroshenko, O. Karpash, O. Shсhyrba, S. Matkivskyi, O. Ivanov, H. Protsiuk, Experimental Studies of Efficient Wells Completion in Depleted Gas Condensate Fields by Using Foams, Strojnícky Časopis – Journal of Mechanical Engineering 72/2 (2022) 219-238. DOI: https://doi.org/10.2478/scjme-2022-0031
  • [29] N. Rebai, A. Hadjadj, A. Benmounah, A.S. Berroukc, S.M. Boualleg, Prediction of natural gas hydrates formation using a combination of thermodynamic and neural network modeling, Journal of Petroleum Science and Engineering 182 (2019) 106270. DOI: https://doi.org/10.1016/j.petrol.2019.106270
  • [30] A.N. El-hoshoudy, A. Ahmed, S. Gomaa, A. Abdelhady, An Artificial Neural Network Model for Predicting the Hydrate Formation Temperature, Arabian Journal for Science and Engineering 47 (2022) 11599-11608. DOI: https://doi.org/10.1007/s13369-021-06340-w
  • [31] Y. Seo, B. Kim, J. Lee, Y. Lee, Development of AI-Based Diagnostic Model for the Prediction of Hydrate in Gas Pipeline, Energies 14/8 (2021) 2313. DOI: https://doi.org/10.3390/en14082313
  • [32] S.J.A.K. Sahith, S.R. Pedapati, B. Lal, Application of Artificial Neural Networks on Measurement of Gas Hydrates in Pipelines, Test Engineering and Management 81 (2022) 5769-5774.
  • [33] S.S. Haykin, Neural Networks: A Comprehensive Foundation, Second Edition, Prentice-Hall of India Pvt. Limited, India, 1999.
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9b5bce27-4042-49db-acd9-a7ae8aeb0f1e
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