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Editor-in-Chief
Nikiforov
Vladimir O.
D.Sc., Prof.
Partners
doi: 10.17586/2226-1494-2020-20-1-82-93
PERSPECTIVE DEVELOPMENT OF ENERGY SYSTEMS IN CONDITIONS OF RUSSIAN ECONOMY DIGITAL TRANSFORMATION
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Article in Russian
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Abstract
For citation:
Mozokhin An. E., Mozokhin Al. E. Perspective development of energy systems in conditions of Russian economy digital transformation. Scientific and Technical Journal of Information Technologies, Mechanics and Optics, 2020, vol. 20, no. 1, pp. 82–93 (in Russian). doi: 10.17586/2226-1494-2020-20-1-82-93
Abstract
Subject of Research. The paper presents the reasons for transition to digital energy and the development of intelligent electrical networks. We study the impact of global and local challenges in the framework of the development of digital energy areas and smart electric networks in Russia on the socio-economic and technological sectors of the country. The practices used in developed and developing countries are evaluated for support and stimulation of the state innovation policy and private investments. Method. Comparative analysis of measures was carried out for support and stimulation of innovative activities of the fuel and energy complex in the framework of economy digital transformation concept in the USA, the European Union, Asia and Russia. We gave an expert assessment of the impact of global challenges in the framework of the chosen research area on the Russian society social and technological side of life. Main Results. Evaluation model has been developed for assessing the impact of global challenges on technological development in the field of digital technologies and smart energy. Analysis of the internal and external causes of the transition to digital energy and the development of intelligent electrical networks is carried out. The existing and perspective technologies of digital transformation of the electric grid complex for the perspective until 2030 are compared; advanced and outsider technologies are highlighted. The potential growth points of domestic and foreign power grid companies in the near and long term are identified. Key tools and measures for support of innovative businesses are grouped by the degree of their impact on the implementation of digital technologies and smart systems in the energy sector. Practical Relevance. Recommendations are formulated on the implementation of policies in the field of digital energy and smart electric networks for the Russian Federation based on the analysis of the best practices for the introduction of digital technologies in the energy sector, as well as on evaluation of the effectiveness of tools for support and stimulation of innovative activity in the industry.
Keywords: digital energy, smart electric networks, energy development forecast, innovation, digital transformation
References
References
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2. Mozokhin A.E., Shvedenko V.N. Digitization development directions of national and foreign energy systems. Scientific and Technical Journal of Information Technologies, Mechanics and Optics, 2019, vol. 19, no. 4, pp. 657–672 (in Russian). doi: 10.17586/2226-1494-2019-19-4-657-672
3. Digital transition in the power industry of Russia. Expert and analytical report from 13.09.2017. Center for Strategic Research, 2017, 47 p. Available at: https://csr.ru/wp-content/uploads/2017/09/ Doklad_energetika-Web.pdf (accessed: 14.10.2019). (in Russian)
4. Oil and Gas Journal Russia. World energy consumption will increase by 2035 by 41% — BP. Available at: http://ogjrussia.com/news/view/ mirovoe-potreblenie-energii-vozrastet-k-2035-godu-na-41-bp (accessed: 14.10.2019). (in Russian)
5. Strategy 2020: A new growth model – a new social policy. Final report on the results of expert work on pressing problems of Russia’s socio-economic strategy for the period until 2020. Book 1. Ed. by
V.A. Mau, Ya.I. Kuzminov. Moscow, Publishing House “Delo” RANEPA, 2013, 430 p. (in Russian)
6. Arefev N.V. The development of infrastructure in Russia at the present stage. The second volume of the information-analytical publication “Infrastructure of Russia”. Vol. 2. 2013. Available at: http://federalbook.ru/files/Infrastruktura/Soderjaniye/Tom-2/III/ Arefyev.pdf (accessed: 14.10.2019). (in Russian)
7. The role of RES-based microgeneration in the development of distributed energy in Russia. Moscow School of Management Skolkovo. 2017. Available at: https: //energy.skolkovo.ru/downloads/ documents/SEneC/News/SKOLKOVO_EneC_2017.11.01_Khokhlov. pdf (accessed: 14.10.2019). (in Russian)
8. Abakumova K.N. Modern trends in the development of science and innovation. Modern trends in education and science: Sat. scientific tr according to the materials of the Intern. scientific-practical conf. Part 10. Tambov, 2014, pp. 8–10. (in Russian)
9. New energy forecasts. Energy Bulletin, 2018, no. 66. Available at: http://ac.gov.ru/files/publication/a/19857.pdf (accessed: 14.10.2019). (in Russian)
10. The mechanism of strategic planning in the implementation of the concept of Smart Grid. Available at: https://docplayer.ru/34232951- Mehanizm-strategicheskogo-planirovaniya-v-realizacii-koncepcii- smart-grid.html (accessed: 14.10.2019). (in Russian)
11. Kobets B.B., Volkova I.O. Innovative development of the electric power industry based on the Smart Grid concept. Available at: https:// www.hse.ru/data/2013/01/23/1306487070/SmartGrid_monografia. pdf (accessed: 14.10.2019). (in Russian)
12. Masera M., Bompard E.F., Profumo F., Hadjsaid N. Smart (electricity) grids for smart cities: assessing roles and societal impacts. Proceedings of the IEEE, 2018, vol. 106, no.4, pp. 613–625. doi: 10.1109/JPROC.2018.2812212
13. Du Y., Tu H., Lukic S., Lubkeman D., Dubey A., Karsai G. Development of a controller hardware-in-the-loop platform for microgrid distributed control applications. Proc. 3rd IEEE International Workshop on Electronic Power Grid (eGrid 2018), 2018, pp. 8598696. doi: 10.1109/eGRID.2018.8598696
14. Zhao C., Chen J., He J., Cheng P. Privacy-preserving consensus-based energy management in smart grids. IEEE Transactions on Signal Processing, 2018, vol. 66, no. 23, pp. 6162–6176. doi: 10.1109/ TSP.2018.2872817
15. Wang K., Hu X., Li H., Li P., Zeng D., Guo S. A Survey on energy internet communications for sustainability. IEEE Transactions on Sustainable Computing, 2017, vol. 2, no. 3, pp. 231–254. doi: 10.1109/TSUSC.2017.2707122
