English
Русский 42-57 p.
The paper holds that the disposal of offshore oil platforms (OOP) after the expiration of their lifecycle is inexpedient and unjustified from the environmental standpoint, since this process results in a dramatic adverse impact imposed on the hydrosphere, which explains the relevance of OOP conver-sion into objects with other functional purposes. The focus is on the global experience of converting offshore oil platforms into residential and industrial buildings. Special attention is paid to the fact that the conversion of an object leads to a reduced construction timeline, which is possible due to optimiz-ing the timeframe of dismantling works that become unnecessary during the subsequent operation of the OOP structural parts. The point is emphasized that OOP repurposing, and in particular creating so-called floating cities on their basis, is capable of meeting a handful of environmental, socioeconomic and town-planning challenges, which however calls for a rigorous professional approach and a thor-ough study of the OOP lifecycle stages both before and after their functional conversion. This, in turn, may lay the ground for the development of an information model of OOP functional repurposing. The research is aimed to explore the specifics of developing an information model of OOP conversion into other type facilities, and as such identifies the key OOP types (submersion depth and underwater de-sign solutions, principal advantages and disadvantages) required to build individual information blocks to form part of the overarching information model of OOP conversion. Also, a scheme of information environments is provided showing the algorithm of creating an information model of OOP conversion and singling out the stages of various lifecycle phases.
The conclusion is made that the functional repurposing of offshore oil platforms is required to as-sure safety of the natural environment, suggesting that the assessment of the environmental perfor-mance and energy efficiency of the organizational and technological solutions of OOP functional con-version must be made part of the front-end design engineering milestone.
The conclusion is made that the functional repurposing of offshore oil platforms is required to as-sure safety of the natural environment, suggesting that the assessment of the environmental perfor-mance and energy efficiency of the organizational and technological solutions of OOP functional con-version must be made part of the front-end design engineering milestone.
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[24] Zubkov S.K., Dryakhlov V.S., Kamensky G.A., Rezanov K.S. Modular drilling rigs for im-proving the efficiency of offshore production. Business Journal Neftegaz.RU. 2023. 1 (131). P. 46 – 51. (rus.)
[25] Klyuyev S.V., Kashapov N.F., Radaykin O.V., Sabitov L.S., Klyuyev A.V., Shchekina N.A. Reliability coefficient for fibreconcrete material. Construction Materials and Products. 2022. 5 (2). P. 51 – 58. https://doi.org/10.58224/2618-7183-2022-5-2-51-58
[2] Topchiy D.V., Muzychenko S.G., Gotsoev S.D. Formation of the structure for calculating the effectiveness of the organization of control of organizational and technological processes during reprofiling. Bulletin of Eurasian Science. 2019. 11 (5). P. 7. URL: https://esj.today/PDF/90SAVN519.pdf (rus.)
[3] Zhilenko O.B., Nimetullayeva U.M. Adaptation of existing buildings to a new function. Construction and technogenic safety. 2021. 2 (73). P. 17 – 26. (rus.)
[4] Ann Scarborough Bull, Milton S. Love. Worldwide oil and gas platform decommissioning: A review of practices and reefing options. Ocean and Coastal Management. 2019. P. 168. 274 DOI: 10.1016/j.ocecoaman.2018.10.024
[5] Abandoned oil platforms fell in love with marine life and became a framework for new reefs [Electronic resource]. URL: https://fb.ru/post/nature/2021/1/31/282747 (data of access: 03.12.2022) (rus.)
[6] Khalidov I., Milovidov K., Soltakhanov A. Decommissioning of oil and gas assets: in-dustrial and environmental security management, international experience and Russian prac-tice. Heliyon. 2021. 7 (7). P. e07646. URL: https://www.cell.com/action/showPdf?pii=S2405-8440821901749-7
[7] What benefits will abandoned oil platforms bring to the ocean [Electronic resource]. URL: https://travelask.ru/blog/posts/9133-kakuyu-polzu-okeanu-prinesut-zabroshennye-neftyanye-platform (data of access: 03.12.2022) (rus.)
[8] New use of abandoned oil rigs [Electronic resource]. URL: https://energosmi.ru/archives/47621 (data of access: 03.12.2022) (rus.)
[9] Nugraha R.B.A., Basuki R., Oh J.S., Cho I.I.H., Naibaho N., Secasari Y., LON Mbay. Rigs-To-Reef (R2R): A new initiative on re-utilization of abandoned offshore oil and gas plat-forms in Indonesia for marine and fisheries sectors. IOP Conference Series: Earth and Envi-ronmental Science. 2019. 241. P 012014 DOI: 012014. 10.1088/1755-1315/241/1/012014
[10] Radhouane Ben-Hamadou, Ahmad M.D. Mohamed, Sarra N. Dimassi, Mariam M. Razavi, Sara M. Alshuiael, and Muhammad O. Sulaiman. Assessing and Reporting Poten-tial Envi-ronmental Risks Associated with Reefing Oil Platform During Decommission-ing in Qatar. In book: Sustainable Qatar, Social, Political and Environmental Perspec-tives. 2022. P. 167 – 191. DOI: 0.1007/978-981-19-7398-7_10
[11] Chiemela V.A., Ahmed R., Harrison O.B., Idris A.J., Chen A. Review on Fixed and Floating Offshore Structures. Part I: Types of Platforms with Some Applications. Journal of Marine Science and Engineering. 2022. 10 (8). P. 1074. DOI: https://doi.org/10.3390/jmse10081074
[12] Kee K.Y., Sue-Wern H. Transforming Abandoned Oil Rigs into Habitable Structures. Social Design. 2011. URL: https://ru.socialdesignmagazine.com/mag/architettura/ku-yee-kee-hor-sue-wern-trasformare-piattaforme-petrolifere-abbandonate-in-strutture-abitabili
[13] Wan Abdullah Zawawi, Liew M.S., Na K.L. Decommissioning of Offshore Platform: A Sus-tainable Framework. CHUSER 2012. IEEE Colloquium on Humanities, Science and Engi-neering Research. 2012. P. 26 – 31. DOI: 10.1109/CHUSER.2012.6504275
[14] Benai H.A., Balyuba I.G., Radionov T.V. Dynamic improvement of buildings and structures during reconstruction as a fundamental process of transformation of the architectural envi-ronment of cities in the conditions of development of innovative technologies. Modern in-dustrial and civil construction. 2017. 13 (1_. P. 37 – 45. (rus.)
[15] Mudretsova G.G., Chistyakov K.Yu. Ways of architectural and structural shaping of convert-ible offshore oil-producing complexes. System technologies. 2020. 4. P. 84 – 99. (rus.)
[16] Tsepilova O.P. Investigation of methods for determining the function during repeated adap-tation of industrial complexes. Bulletin of BSTU named after V.G. Shukhov. 2022. . P. 63 – 76. DOI: 10.34031/2071-7318-2022-7-9-63-76 (rus.)
[17] Cheng J.C.P., Tan, Y., Song, Y. et al. A semi-automated approach to generate 4D/5D BIM models for evaluating different offshore oil and gas platform decommissioning options. Vis-ualization in Engineering. 2017. 5 (12). P. 1 – 13. DOI: 10.1186/s40327-017-0053-2.
[18] Abramyan S.G., Burlachenko O.V., Oganesyan O.V., Burlachenko A.O., Pleshakov V.V. Possibilities of digital technologies for each stage of the life cycle of a construction system. Bulletin of the Volgograd State University of Architecture and Civil Engineering. Series: Construction and Architecture. 2022. 2 (87). P. 317 – 325. (rus.)
[19] Abramyan S.G., Burlachenko O.V., Oganesyan O.V., Burlachenko А.O., Archakov I.B., Ple-shakov V.V. Technological solutions ensuring reliable operation of steel vertical reservoirs in seismic areas. Construction Materials and Products. 2022. 5 (5). P. 5 – 16. https://doi.org/10.58224/2618-7183-2022-5-5-5-16
[20] Tcharo Honore, Vorobyev A.E., Vorobyev K.A. Digitalization of the oil industry: basic ap-proaches and justification of "intelligent" technologies. Bulletin of Eurasian Science. 2018. 10 (2). P. 17. URL: https://esj.today/PDF/88NZVN218.pdf (rus.)
[21] Menelyuk A.I., Lobanova L.V. Algorithm for choosing an effective solution for re-profiling industrial buildings. Bulletin of the Pridneprovskaya State Academy of Construction and Ar-chitecture. 2016. 8 (221). P. 35 – 41. (rus.)
[22] Inzartsev L.V., Kiselev V.V., Kostenko Yu.V., Matvienko A.M., Pavin A.F., Shcherbatyuk A.V. Underwater robotic complexes: systems, technologies, applications. Ed. L.V. Kiselev; FSB Institute of Problems of Marine Technologies FEB RAS. Vladivostok. 2018. 368 p. (rus.)
[23] Kamensky G.A., Rezanov K.S., Zubkov S.K. On expanding the possibilities of using un-manned platforms on the shelf of the Russian Federation. Drilling and oil. 2023. № 01. Spec. release. [electronic resource]. URL: https://burneft.ru/archive/issues/2023-01sp/64 (date of access: 05.05.2023) (rus.)
[24] Zubkov S.K., Dryakhlov V.S., Kamensky G.A., Rezanov K.S. Modular drilling rigs for im-proving the efficiency of offshore production. Business Journal Neftegaz.RU. 2023. 1 (131). P. 46 – 51. (rus.)
[25] Klyuyev S.V., Kashapov N.F., Radaykin O.V., Sabitov L.S., Klyuyev A.V., Shchekina N.A. Reliability coefficient for fibreconcrete material. Construction Materials and Products. 2022. 5 (2). P. 51 – 58. https://doi.org/10.58224/2618-7183-2022-5-2-51-58
Abramyan S.G., Klyuev S.V., Polyakov V.G., Sabitova T.A., Akopyan G.O., Guseynov K.M. Specifics of information model development for functional conversion of offshore oil platforms. Construction Materials and Products. 2023. 6 (4.) P. 42 – 57. https://doi.org/10.58224/2618-7183-2023-6-4-42-57