Problems of development of innovative power supply systems of Ukraine in the context of European integration
- Details
- Category: Content №5 2022
- Last Updated on 30 October 2022
- Published on 30 November -0001
- Hits: 3153
Authors:
H.Pivniak, orcid.org/0000-0002-8462-2995, Dnipro University of Technology, Dnipro, Ukraine, email: This email address is being protected from spambots. You need JavaScript enabled to view it.
O.Aziukovskyi, orcid.org/0000-0003-1901-4333, Dnipro University of Technology, Dnipro, Ukraine, email: This email address is being protected from spambots. You need JavaScript enabled to view it.
Yu.Papaika, orcid.org/0000-0001-6953-1705, Dnipro University of Technology, Dnipro, Ukraine, email: This email address is being protected from spambots. You need JavaScript enabled to view it.
I.Lutsenko, orcid.org/0000-0001-6406-2364, Dnipro University of Technology, Dnipro, Ukraine, email: This email address is being protected from spambots. You need JavaScript enabled to view it.
N.Neuberger, Esslingen University of Applied Sciences, Geppingen, the Federal Republic of Germany, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 2022, (5): 089 - 103
https://doi.org/10.33271/nvngu/2022-5/089
Abstract:
Purpose. To analyse problems and features of the formation of perspective concepts and scenarios for the development of the latest structures of energy supply systems for Ukraine in the context of the energy transition and European integration.
Methodology. Theoretical studies, analysis, and generalization of scientific and practical results along with the comparative analysis.
Findings. The European Green Deal contributes to the wide development of relevant RES-based systems in the EU countries. Ukraine has also declared its active position regarding the issues of low-carbon development and green transition with the formation of relevant implementation scenarios until 2035, 2050, and 2070. The paper analyses the current state and structure of the electricity supply system in Germany and Ukraine on their ways to low-carbon development of the energy sector and economy. As a result of the conducted research, it is possible to determine further rational steps for effective transformation of the electric power industry according to the strategy of pragmatic or low-carbon development with further measures to modernize the nuclear and thermal energy sectors and moderate RES development. Development of rational structures of electric power systems of new technological order is a constantly relevant, science-intensive direction, which brings serious changes to the traditional raw-resource economy and energy industry.
Originality. The conducted comprehensive analysis of the current state and prospects for the development of the structure of electric power complexes of Ukraine and Germany makes it possible to formulate high-priority rational steps in achieving energy independence and energy security, taking into account low-carbon development of the national economy.
Practical value. The represented analytics can be used to ensure sustainable development of Ukrainian energy industry, to form an outlook on problems, prospects, and aspects of optimistic and pessimistic scenarios of the generation system development.
Keywords: electric power, energy transition, low-carbon development, energy development scenarios
References.
1. World Energy & Climate Statistics Yearbook 2022 (2022). Retrieved from https://yearbook.enerdata.net/total-energy/world-consumption-statistics.html.
2. Germanys energy consumption and power mix in charts (2022). Retrieved from https://www.cleanenergywire.org.
3. Installed power capacity of IPS of Ukraine (2022). Retrieved from https://ua.energy.
4. CG Scientific and Technical Union of Power Engineers and Electrical Engineers of Ukraine edition of the STUPE (2022). Enerhoinform-Informenerho No. 605. On the main indicators of the operation of the FEC of Ukraine FOR JANUARY-DECEMBER 2021 No. 605. Retrieved from https://www.ntseu.net.ua.
5. Report on the assessment of compliance (sufficiency) of generating capacities in Ukraine 2019 (2019). Retrieved from https://ua.energy/?page_id=13075.
6. Dispatch information of NEC Ukrenergo PJSC (2022). Retrieved from https://ua.energy/diyalnist/dyspetcherska-informatsiya/.
7. Schedules of production and consumption of electricity in the energy system of Ukraine (n.d.). Retrieved from https://ua.energy/diyalnist/dyspetcherska-informatsiya/dobovyj-grafik-vyrobnytstva-spozhyvannya-e-e/.
8. Clarifications on the limitation of generation of SPP and WPP from January 1, 2020 (2020). Retrieved from https://ua.energy/zagalni-novyny/roz-yasnennya-shhodo-obmezhennya-generatsiyi-ves-ta-ses-7-sichnya-2020-roku/.
9. Golovko, I., & Astakhova, T. (n.d.). Briefing of the Centre for Environmental Initiatives Ekodiya. Why should Ukraine develop decentralized energy even today? Retrieved from https://setech.in.ua/ru/potchemu-v-ukraine-sleduet-razvivaty-detsentralizovannuyu-nergetiku-uzhe-segodnya/.
10. Kalinchyk, V.P., & Skachok, O.V. (n.d.). Evaluation and analysis of methods for levelling load curves of production systems. Retrieved from http://ela.kpi.ua/jspui/bitstream/123456789/11308/1/7_Kalinchyk_V_Assessment.
11. Levelling the electrical load curves of the power system (n.d.). Retrieved from http://www.energetika.by/arch/~page__m21=10~news.
12. Khatskevych, Yu.V., Lutsenko, I.M., & Rukhlov, A.V. (2017). Perspectives of load management in energy system with the help of electric vehicles. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (5), 86-93.
13. Pivnyak, G., Azukovskiy, O., Papaika, Yu., Careres Cabana, E., Olczak, P., & Dyczko, A. (2021). Assessment of power supply energy efficiency by voltage quality criterion. Rynek Energii, (4), 75-84.
14. Papaika, Yu.A., Lysenko, O.H., Koshelenko, Ye.V., & Olishevskyi, I.H. (2021). Mathematical modeling of power supply reliability at low voltage quality. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (2), 97-103. https://doi.org/10.33271/nvngu/2021-2/097.
15. Robinson, A.P., Blythe, P.T., Bell, M.C., Hbner, Y., & Hill,G.A. (2013). Analysis of electric vehicle driver recharging demand proles and subsequent impacts on the carbon content of electric vehicle trips. Energy Policy, 61, 337-348.
16. Bondarchuk, .S. (2015). Predicted energy, economic, and ecological efficiency of the implementation of network solar power stations under market conditions. Electrotechnical and computer systems, 20(96), 51-55.
17. Godina, R., Rodrigues, E., Matias, J., & Catalo, J. (2015). Effect of Loads and Other Key Factors on Oil-Transformer Ageing: Sustainability Benefits and Challenges. Energies, 8, 12147-12186.
18. Lutsenko, .., & Tsygan, P.S. (2017). Technical and economic aspects of the use of electric vehicles in the electric networks of Ukraine. Visnyk of KrNU, 6/2017, 21-30.
19. Vinnichuk, Yu. (2018). How did VAT abolishment influence the electric vehicle import in Ukraine. Retrieved from https://biz.censor.net.ua/resonance/3099495/yak_skasuvannya_pdv_vplinulo_na_mport_elektromoblv_v_ukranu.
20. Registered and predicted fleet of trucks and LCV electric vehicles (electric vehicles and hybrids) in Ukraine (2019). Retrieved from http://irsgroup.com.ua/.
21. Lutsenko, .., Fedoryachenko, S.., Maliienko, .V., Rukhlova,N.Yu., Koshelenko, Ye.V., & Tsygan, P.S. (2021). Assessing the potential of increase in energy efficiency in SmartGrid-systems with prosumers on the basis of electric vehicles. Visnyk of KhNADU, (95), 241-251.
22. Balakhontsev, A., Beshta, O., Boroday, V., Khudolii, S., & Pirienko, S. (2021). A Review of Topologies of Quick Charging Stations for Electric Vehicles. International Conference on Modern Electrical and Energy Systems (MEES), 1-4. Retrieved from https://ieeexplore.ieee.org/abstract/.
23. Pivnyak, G.G.,& Beshta, O.O. (2020) A complex source of electrical energy for three-phase current based on a stand-alone voltage inverter. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (1), 89-93. https://doi.org/10.33271/nvngu/2020-1/089.
24. The geopolitics of the European Green Deal (2021). Retrieved from https://ecfr.eu/publication/the-geopolitics-of-the-european-green-deal/.
25. Verkhovna Rada of Ukraine (n.d.). National security strategy of Ukraine. Retrieved from https://zakon.rada.gov.ua/laws/show/392/2020#n12.
26. State and prospects for the development of technologies of smart power grids, demand management, and mode control systems in terms of development of renewable energy sources in the foreign energy sector (2018). Retrieved from https://ua.energy/wp-content/uploads/2018/04/1.-Stan-rozvytku-smart-grid.pdf.
27. SE NEC Ukrenego. -PROJECTS (n.d.). Retrieved from https://ua.energy/diyalnist/projects/spilni-proekty-z-mfi/#1538032249035-96c4bd2a-d9fc1cf7-ff2a.
28. Verkhovna Rada of Ukraine (2016). Cabinet of Ministers of Ukraine. Decree of 13 July 2016 No. 552- on approval of the Programme of the development of hydroenergetics for the period up to 2026. Retrieved from https://zakon.rada.gov.ua/laws/show/552-2016-%D1%80.
29. Minutes of a working meeting on the formation of prospective scenarios of hydroenergetics development in terms of preparation of the draft of the Report on compliance (sufficiency) assessment of generating units (2019). Retrieved from https://ua.energy/wp-content/uploads/2019/11/Protokol-vid-02.10.2019.pdf.
30. Concept of green energy transition of Ukraine up to 2050 (2020). Retrieved from http://mpe.kmu.gov.ua/minugol/control/uk/publish/article;jsessionid=12D73B364595AE9BC3059133CE27EA7A.app1?art_id=245434883&cat_id=35109.
31. European Commission: A European Green Deal (2022). Retrieved from https://ec.europa.eu/info/strategy/priorities-2019-2024/european-green-deal_en/.
Newer news items:
- A new approach on AI application for grounding resistor prediction in underground mines of Vietnam - 30/10/2022 01:53
- Investigation of the influence of hyperthermia and soil pollution with the petrochemicals on test objects using the method of mathematical planning - 30/10/2022 01:53
- Efficiency assessment of water resources management and use by simplified indicators - 30/10/2022 01:53
- Ecologization of market behavior of consumers and management business strategies - 30/10/2022 01:53
- Entrepreneurial structures of the extractive industry: foreign experience in environmental protection - 30/10/2022 01:53
- Dichotomy of legal provision of ecological safety in excavation, extraction and use of coal mine methane - 30/10/2022 01:53
- Planning models of sanitary protection zones around mode-forming objects - 30/10/2022 01:53
- Criminal liability for illegal mining: analysis of legislative novelties - 30/10/2022 01:53
- Legal security of environmental safety under the conditions of marital state in Ukraine - 30/10/2022 01:53
- A risk of pulmonary diseases in miners while using dust respirators - 30/10/2022 01:53
Older news items:
- Estimation and forecasting of carbon dioxide emissions from coal-fired thermal power plants in Ukraine - 30/10/2022 01:53
- Mathematical simulation of autonomous wind electric installation with magnetoelectric generator - 30/10/2022 01:53
- Experimental evaluation of fire hazard of lithium-ion battery during its mechanical damage - 30/10/2022 01:53
- Substantiating the methods for calculating the split cylindrical drums of mine hoisting machines with increased rope capacity - 30/10/2022 01:53
- Load of the wagon-platform for transportation of bulk cargoes - 30/10/2022 01:53
- Impact of weak electromagnetic fields on the properties of coal substance - 30/10/2022 01:53
- Use of natural phosphate wastes in the manufacture of construction bricks - 30/10/2022 01:53
- Forecasting the technical efficiency of mobile workover rigs - 30/10/2022 01:53
- Substantiation of the optimal parameters of the bench elements and slopes of iron ore pits - 30/10/2022 01:53
- Peculiarities of drilling hard rocks using hydraulic shock technology - 30/10/2022 01:53