1. LSULS Digital Repository
  2. Навчально-наукові підрозділи / Academic and Research Units
  3. Кафедра цивільного захисту та протимінної діяльності
  4. Гаврись Андрій Петрович
  5. 2023
Please use this identifier to cite or link to this item: https://sci.ldubgd.edu.ua/jspui/handle/123456789/11901
Title: Development of the methodology of energy and environmental safety of Ukraine based on own geothermics
Other Titles: Розроблення методології енергетичної, екологічної та продовольчої безпеки України на основі власних геотермальних ресурсів
Authors: Стародуб, Юрій Петрович
Карпенко, В.М.
Гаврись, Андрій Петрович
Беген, Д.А.
Keywords: civil protection
digital ecological and technological model
Issue Date: 2023
Publisher: Збірник наукових праць «Геофізичний журнал». – Київ. – 2023. - 45(4). – с. 128-135.
Citation: Ahmed,A.A., Assadi,M., Kalantar,A., Sliwa,T., & Sapińska-Śliwa,A. (2022). A critical review on the use of shallow geothermal energy sys-tems for heating and cooling purposes. Ener-gies, 15(12), 4281. https://doi.org/10.3390/en15124281.Balázs,A., Gerya,T., May,D., & Tari,G. (2023). Cont rasting transform and passive margin sub sidence history and heat flow evolution: In sights from 3D thermo-mechanical mode-ling (Vol.524, pp.SP524—2021). Geol. Soc., Lon don, Spec. Publ. https://doi.org/10.1144/SP524- 2021-94.Beall,A., Fagereng,Å., Davies,J.H., Garel,F., & Davies,D.R. (2021). Influence of subduc-tion zone dynamics on interface shear stress and potential relationship with seismogenic behavior. Geochemistry, Geophysics, Geosys-tems, 22(2), e2020GC009267. https://doi.org/ 10.1029/2020GC009267.Buzan,J.R., & Huber,M. (2020). Moist heat stress on a hotter Earth. Annual Review of Earth and Planetary Sciences, 48, 623—655.Dai,F., Masuda,K., Winn,J.N., & Zeng,L. (2019). Homogeneous analysis of hot earths: Masses, sizes, and compositions. The Astrophy sical Jour-nal, 883(1), 79.https://doi.org/10.3847/1538-4357/ab3a3b.Davies,J.H., & Davies,D.R. (2010). Earth’s surface heat flux. Solid Earth, 1(1), 5—24, https://doi.org/10.5194/se-1-5-2010.Guo,A., Yang,J., Sun,W., Xiao,X., Cecilia,J.X., Jin,C., & Li,X. (2020). Impact of urban mor-phology and landscape characteristics on spa tiotemporal heterogeneity of land surface temperature. Sustainable Cities and So ci ety, 63, 102443.https://doi.org/10.1016/j.scs.2020. 102443.He,B.J., Wang,J., Liu,H., &Ulpiani,G. (2021). Lo calized synergies between heat waves and ur ban heat islands: Implications on human ther mal comfort and urban heat management. En vironmental Research, 193, 110584. https://doi.org/10.1016/j.envres.2020.110584.ReferencesHerndon,J.M. (2007). Solar System processes underlying planetary formation, geodyna-mics, and the georeactor. In Neutrino Geophy-sics: Proceedings of Neutrino Sciences 2005(pp.53—89). Springer New York. https://doi.org/10.1007/978-0-387-70771-6_6.Heymann,Y. (2014). The dichotomous cosmology with a static material world and expan ding luminous world. Progress in Physics, 10(3), 178—181.Ivanusa,A., Yemelyanenko,S., Yakovchuk,R., & Ivanusa,Z. (2019). Safety-focused stakeholder management in civil protection projects. Inter-national Scientific and Technical Conference on Computer Sciences and Information Tech-nologies (pp.27—31). https://doi.org/10.1109/STC-CSIT.2018.8929847.Karpenko,V., Starodub,Y., & Havrys,A. (2021). Com puter Modeling in the Application to Geo thermal Engineering. Advances in Civil En gineering, 6619991. https://doi.org/ 10.1155/2021/ 6619991.Lay,T., Hernlund,J., & Buffett,B.A. (2008). Core-mantle boundary heat flow. Nature Geoscience, 1(1), 25—32. https://doi.org/10.1038/ngeo.2007.44.Lischenko,L.P., & Kudrashov,О.І. (2021). The re-sults of the studyof spatio-temporalchanges in surfacetemperaturesof Zaporizhya based on satellite data. Ukrainian Journal of Remote Sensing, 8(3), 27—36. https://doi.org/10.36023/ujrs.2021.8.3.198 (in Ukrainian).Luque,R., Pallé,E., Kossakowski,D., Dreizler,S., Kemmer,J., Espinoza,N., ... & Wohler,B. (2019). Planetary system around the nearby M dwarf GJ 357 including a transiting, hot, Earth-sized planet optimal for atmospheric charac-terization. Astronomy & Astrophysics, 628, A39. https://doi.org/10.1051/0004-6361/201935801.Pollack,H.N., Hurter,S.J., & Johnson,J.R. (1993). Heat flow from the Earth’s interior: Analysis of the global data set. Reviews of Geophysics, 31(3), 267. https://doi.org/10.1029/93rg01249.Popovych,V., & Voloshchyshyn,A. (2019). Envi-ronmental impact of devastated and scapes of Volynian Upland and Male Polisya (Ukraine). Environmental Research, Engineering and Management, 75(3), 33—45. https://doi.org/10. 5755/j01.erem.75.3.23323.Sliwa,T., Sapińska-Śliwa,A., Gonet,A., Kowal-ski,T., & Sojczyńska,A. (2021). Geothermal Boreholes in Poland — Overview of the Cur-rent State of Knowledge. Energies, 14(11), 3251. https://doi.org/10.3390/en14113251.Sliwa,T., & Rosen,M.A. (2015). Natural and arti-fi cial methods for regeneration of heat re-sour ces for borehole heat exchangers to en-hance the sustainability of underground ther-mal storages: A review. Sustainability, 7(10), 13104—13125. https://doi.org/10.3390/su710 13104.Starodub,Y., Karabyn,V., Havrys,A., Kovalchuk,V.,Rogulia,A., & Yemelyanenko,S. (2022). Geo-physical research in the pre-Car pa thian hy-drosphere situation forthe environmental civil protection purposes. Geofizicheskiy Zhurnal, 44(4), 171—182. https://doi.org/10.24028/gj. v44i4.264847.Starodub,Y., Karpenko, V., Karabyn, V., & Shu-ryhin, V. (2020). Mathematical Modeling of the Earth Heat Processes for the Purposes of Eco-technology and Civil Safety. IEEE 15th International Conference on Computer Sci-ences and Information Technologies (CSIT), Zbarazh, Ukraine (pp. 146—149). https://doi.org/10.1109/CSIT49958.2020.9322009.Vogel,M.M., Zscheischler,J., Wartenburger,R., Dee,D., & Seneviratne,S.I. (2019). Concur-rent 2018 hot extremes across Northern Hemi-sphere due to human-induced climate change. Earth’s Future, 7(7), 692—703. https://doi.org/10.1029/2019EF001189.Yemelyanenko,S., Rudyk,Y., Kuzyk,A., & Ya-kovchuk,R. (2018).Geoinformational systemof rescue services. Paper presented at theMATEC Web of Conferences, 247.https://doi. org/10.1051/matecconf/201824700030.Zimmermann,L., Moritz,K., Kennel,M., & Bit-tersohl,J. (2000). Influence of bark beetle in-festation on water quantity and quality in the Grosse Ohecatchment (Bavarian Forest Na-tional Park). Silva Gabreta, 4(5), 1—62. https://doi.org/10.1111/conl.12153.
Abstract: The article presents an idea of the project that defines the development of a geothermal power plant methodology based on a single isolated well. It is planned to develop a techni-cal and economic rationale and geological and geophysical aspects of the development of geothermal energy and to obtain data on deposits of geothermal water in the deep.Extraction of heat from hot rocks at the pits is to be carried out using a special energy carrier, construction of the operating column, and circulation mode.To create a model in the project, a well is needed with a depth of 4,702m,temperature at the bottom of 130 °С,an unperforated casing string with a diameter of 245mm to a depth of 4,500m, and no formation fluids.The transfer and transformation of the energy carrier by the working body into electric and hydrogen energy is maintained by ORC (Organic Rankine Cycle).Thedevelopment of the methodology includes two stages:The first stage of the project involves legal preparation at the local and state levels for the use of the land plot and technical means of the drilled well and obtaining licenses and permits for the implementation of the project. It is planned to develop a technical and economic feasibility study for the construction of a geothermal electric station that will generate electricity and hydrogen energy for consumers.The second stage of the project involves the technical preparation of the well for its use as part of a geothermal power station. Remediation of the well to a depth of 4,500m is foreseen, as well as the implementation of industrial geophysical studies of the technical condition of the unperforated casing string; conducting preliminary geothermal studies on the stability and thermal productivity of hot rocks.The authors intend to use results in the oil-and-gas industry, which has deep wells that have completed their purpose for hydrocarbon extraction, as well as in the nuclear, metallurgical, chemical, andmany other fields.
URI: https://sci.ldubgd.edu.ua/jspui/handle/123456789/11901
Appears in Collections:2023

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