THE STATE AND PROSPECTS ORGANIZATION OF DECENTRALIZED ELECTRICITY TRADE AT THE REGIONAL LEVEL

Z.Kh. Borukaiev, V.A. Evdokimov, K.B. Ostapchenko

Èlektron. model. 2023, 45(3):11-27

https://doi.org/10.15407/emodel.45.03.011

ABSTRACT

The article is devoted to the analysis of problems and experience of conducting research on the implementation of Smart Grid and Demand Response concepts in power supply systems with sources of distributed, decentralized generation and active consumers in power systems. The issue of finding ways to solve the scientific and technical problems of implementing the concepts of Smart Grid and Demand Response when solving the tasks of designing and building local electric power systems, taking into account the peculiarities of their functioning in the unified energy system of Ukraine was considered. The range of under-researched problems of decentralized management development in the retail segment of the electricity market in the organization of micro-markets based on the application of modern approaches of multi-agent management and block chain technology for the business processes organization is outlined. The main tasks of the conceptual design of the new market architecture of micro-markets on local electricity systems and their integration into the existing systems of organizational, operational-technological and information management of the electricity market are presented. Micro-markets are actually developing and, with experience, can become a driver for the post-war development of the market infrastructure in terms of the simultaneous implementation and practical application the Smart Grid and Demand Response principles for the implementation of technical solutions at the retail market level.

KEYWORDS

active consumers, renewable energy sources, electricity generation, local electricity systems, electricity micro-market, smart contract.

REFERENCES

  1. Denisyuk, S.P., Bazyuk, T.M., Fedosenko, M.M. and Yarmolyuk, O.S. (2017), Power supply systems with an active consumer: models and modes, AVERS Publishing House, Kyiv, Ukraine.
  2. Kyrylenko, A.V. ed. (2014), Intelligent electric power systems: elements and modes, Institut elektrodinamiki, Kyiv, Ukraine.
  3. Kyrylenko, O.V. Denysiuk, S.P., Tankevych, S.E. and Baziuk, T.M. (2016), “Information and regulatory support for the organization of multi-agent management of the electric power system with an active consumer”, Informacijni tehnologiyi ta komp’yuterna inzheneriya, no. 1, p. 29―34, available at: http://nbuv.gov.ua/UJRN/Itki_2016_1_6
  4. Security, energy efficiency, competitiveness (2017), Energy strategy of Ukraine for the period until 2035, Decree of the Cabinet of Ministers of August 18, 2017, no. 605-р, available at: https://zakon.rada.gov.ua/laws/show/605-2017-%D1%80#Text (accessed 09.04.2022).
  5. Geyec, V.M. (2022), “The economy of Ukraine in the imperatives of low-carbon development: Report at the scientific session of the General Assembly of the National Academy of Sciences of Ukraine on February 17, 2022”, Bulletin of the National Academy of Sciences of Ukraine, no. 3, p. 8―17, DOI:
    https://doi.org/10.15407/visn2022.03.008
  6. Kyrylenko, O.V. (2022), “Measures and means of transforming Ukraine’s energy industry into an intelligent, ecologically safe system: Report at the scientific session of the General Assembly of the National Academy of Sciences of Ukraine on February 17, 2022”, Bulletin of the National Academy of Sciences of Ukraine, no. 3, p. 18―23, DOI: 
    https://doi.org/10.15407/visn2022.03.018
  7. Pazderin, A.V., Bartolomej, P.I., Vyatkin, V.V., Eroshenko, S.A. and Stupin, M.V. (2013), “Classification and terms of distributed generation systems”, Scientific works of the IV International Scientific and Technical Conference “Electric power industry through the eyes of youth”, Novocherkassk, Russia, Vol. 2, p. 346―350.
  8. Robustova, Yu.V. (2013), “Analysis and classification of distributed generation definitions”, Scientific works of the IV International Scientific and Technical Conference “Electric power industry through the eyes of youth”, Novocherkassk, Russia, Vol. 2, p. 350―354.
  9. Zaitsev, E.O., Kuchanskij, V.V. and Gunko, I.O. (2021), “Improving the operational reliability and efficiency of the robotic electric lines and electrical installation”, International Scientific Journal “Grail of Science”, no. 5, p. 144―152, DOI: 
    https://doi.org/10.36074/grail-of-science
  10. Zharkin, A.F., Novskij, V.O., Martinov, V.V. and Pazeyev, A.G. (2019), “Provision of high quality power supply in distribution networks with renewable energy sources”, Bulletin of the NTU "KhPI", Series: Electric machines and electromechanical energy conversion, no. 20(1345), p. 4―13, DOI:
    https://doi.org/10.20998/2409-9295.2019.20.01
  11. Denysiuk, S.P., Makhlin, P.V., Shram, O.A. and Slynko, V.M. (2022), “Features of opera­ting modes analysis of the power system in areas with alternative electric power sources (wind power plants)”, Tekhnichna Elektrodynamika, no. 1, p. 41―49, DOI:
    https://doi.org/10.15407/techned2022.01.041
  12. Blinov, I.V., Trach, I.V., Parus, Ye.V., Derevianko, D.G. and Khomenko, V.M. (2022), “Voltage and reactive power regulation in distribution networks by the means of distributed renewable energy sources”, Tekhnichna Elektrodynamika, no. 2, p. 60―99, DOI: 
    https://doi.org/10.15407/techned2022.02.060
  13. Bazyuk, T.M. (2016), “Increasing the energy efficiency of local energy supply systems with an active consumer and distributed generation”, Qualifying scientific work of PhD (Tech.), dissertation, 05.14.01, Kyiv, Ukraine, available at: https://ela.kpi.ua/handle/123456789/18289
  14. Denysiuk, S.P. and Kolomiichuk, M.O. (2021), “Evaluation of financial and technical indicators of efficiency of microgrid work in dynamic modes”, Energy: economy, technologies, ecology, no. 3, p. 18―38, DOI: 
    https://doi.org/10.20535/1813-5420.3.2021.251195
  15. Denysiuk, S.P., Derevianko, D.H. and Bielokha, H.S. (2022), “Synthesis of models of local power systems with distributed generation sources”, Tekhnichna Elektrodynamika, no. 4, p. 48―53, DOI: 
    https://doi.org/10.15407/techned2022.04.048
  16. Kyrylenko, O.V., Blinov, I.V., Zaitsev, I.O., Palachov, S.O. and Vasylchenko, V.I. (2022), “International and european standards implementation for uses smart grid concept in IPS of Ukraine”, Proceedings of the Institute of Electrodynamics of the National Academy of Sciences of Ukraine, no. 63, p. 5―12, DOI: 
    https://doi.org/10.15407/publishing2022.63.005
  17. The state and prospects of the development of technologies of "intelligent" power grids, demand management and regime control systems in the conditions of the development of renewable energy sources in the foreign energy sector, available at: https://ua.energy/wp-content/uploads/2018/04/1.-Stan-rozvytku-smart-grid.pdf (accessed 09.04.2022).
  18. Kolosok, S.I. ed. (2019), Experience of building smart energy networks at the international level: monograph, Sumy State University, Sumy, Ukraine.
  19. Opryshko, V.P. (2019), “Evaluation of the effectiveness of demand management in power supply systems with an active consumer”, Qualifying scientific work of PhD (Tech.), dissertation, 05.14.01, Kyiv, Ukraine, available at: https://ela.kpi.ua/handle/123456789/29532
  20. Concept of implementation of "smart networks" in Ukraine until 2035, Order of the Cabinet of Ministers of Ukraine dated October 14, 2022, no. 908-р, available at: https://zakon.rada.gov.ua/laws/show/908-2022-%D1%80#Text (accessed 09.02.2023).
  21. Internet of Energy, Website presentation of O. Vermesan, SINTEF Digital, Norway, available at: https://iotweek.blob.core.windows.net/slides2017/WORKSHOPS/Energy%20and%20Home%20Comfort/O.%20Vermesan%20SINTEF%20DIGITAL.pdf (accessed 09.02.2023).
  22. International Renewable Energy Agency (2019), Innovation Landscape Brief: Market Integration of Distributed Energy Resources, Abu Dhabi, 2019, available at: https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Feb/IRENA_Market_integration_distributed_system_2019.pdf (accessed 19.02.2023).
  23. Mokhor, V.V. and Evdokimov, V.A. (2020), “About creating a multi-agent simulations model of processes pricing in the electricity market”, Electronic modeling, Vol. 42, no. 6, p. 3―17, DOI:
    https://doi.org/10.15407/emodel.42.06.003
  24. Chemerys, O.A. (2019), “Tasks of blockchain technology for electric microgrids”, Problemy informatyzatsii ta upravlinnya, Vol. 1, no. 61, p. 102―107, DOI: 
    https://doi.org/10.18372/2073-4751.1.14045
  25. Kovalchuk, L.V. (2022), “The advantages of using smart contracts in energy and the problems that need to be solved for their use”, Materials of the scientific-practical conference ”Cybersecurity of energy”, G.E.Pukhov Institute for Modeling in Energy Engineering National Academy of Sciences of Ukraine, May 27, 2022, Kyiv, Ukraine, available at: https:// ipme.kiev.ua/wp-content/uploads/2022/05/Матеріали-КБЕ-2022.pdf (accessed 09.02.2023).
  26. Kovalchuk, L.V. and Kuchynska, N.V. (2022), “Prospects for the use of smart contracts in energy and existing vulnerabilities that must be taken into account for the possibility of their use”, Materials of the scientific-practical conference ”Cybersecurity of energy”, G.E. Pukhov Institute for Modeling in Energy Engineering National Academy of Sciences of Ukraine, November 24, 2022, Kyiv, Ukraine.
  27. Mokhor, V.V. and Tsurkan, V.V. (2022), “Integrated information security management system of critical infrastructure facilities in the energy sector”, Materials of the scientific-practical conference ”Cybersecurity of energy”, G.E. Pukhov Institute for Modeling in Ener­gy Engineering National Academy of Sciences of Ukraine, May 27, 2022, Kyiv, Ukraine, available at: https://ipme.kiev.ua/wp-content/uploads/2022/05/Матеріали-КБЕ-2022.pdf (accessed 09.02.2023).

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