Development of a method for determining the structure of mini-grid, taking into account optimal routes of power lines in an area with sharply heterogeneous landscape

This paper presents a method for determining the optimal structure of an isolated electrical network, taking into account the geographical features of the area in which it is located. A distinctive feature of the method is the removal of restrictions on the number of equivalent routes of power transmission lines sought, with subsequent filtering of the routes, taking into account technological and technical limitations. Thus, the obtained method can be used to organize microgrids in areas remote from the Unified National (All-Russian) Energy Grid with distributed generation and load.

1. Rossiyskaya Federatsiya. Postanovleniye. Ob utverzhdenii gosudarstvennoy programmy Rossiyskoy Federatsii «Razvitiye energetiki»: postanovleniye ot 15 aprelya 2014 g. No. 321 [Russian Federation. Resolution. On approval of the state program of the Russian Federation «Energy Development»: Decree dated April 15, 2014 No. 321]. Available at «Consultant Plus» System. (In Russ.).

2. GOST R 55993-2014/IEC/TS 61836:2007. Sistemy fotoelektricheskiye. Terminy, opredeleniya i simvoly [Solar photovoltaic energy systems. Terms, definitions and symbols]. Moscow, 2007. 85 p. (In Russ.).

3. Molodyuk V. V., Isamukhamedov Ya. Sh., Barinov V. A. O razrabotke tselevoy modeli (prototipa) Mini/Microgrid [About development of purposeful model (antetype) Mini / Microgrid] // Energetik. Energetik. 2021. No. 9. P. 48–53. EDN: GGAKFC. (In Russ.).

4. Fishov A. G. Tekhnicheskiye i ekonomicheskiye aspekty sozdaniya minigridov i ikh integratsii s tsentralizovannym energosnabzheniyem [Technical and economic aspects of creating minigrids and their integration with centralized power supply] // Energetik. Energetik. 2022. No. 4. P. 27–34. EDN: CZLOIZ. (In Russ.).

5. Byk F. L., Myshkina L. S. Nadezhnost’ ob”yektov raspredelennoy energetiki [Reliability of distributed energy facilities] // Nadezhnost’ i Bezopasnost’ Energetiki. Safety and Reliability of Power Industry. 2021. Vol. 14, no. 1. P. 45–51. DOI: 10.24223/1999-5555-2021-14-1-45-51. EDN: XRWJGO. (In Russ.).

6. Bintoudi A., Demoulias C. Optimal isolated microgrid topology design for resilient applications // Applied Energy. 2023. Vol. 338 (1). P. 120909. DOI: 10.1016/j.apenergy.2023.120909. (In Engl.).

7. Du S., Wu D., Dai Z. [et al.]. Regional collaborative planning equipped with shared energy storage under multi-time scale rolling optimisation method // Energy. 2023. Vol. 277 (5). P 127680. DOI: 10.1016/j.energy.2023.127680. (In Engl.).

8. Zhou Y., Ma Y., Wang J. [et al.]. Collaborative planning of spatial layouts of distributed energy stations and networks: A case study // Energy. 2021. Vol. 234 (3). P. 121205. DOI: 10.1016/j.energy.2021.121205. (In Engl.).

9. O merakh po realizatsii gosudarstvennoy programmy Khanty — Mansiyskogo avtonomnogo okruga–Yugry «Zhilishchno-kommunal’nyy kompleks i gorodskaya sreda»: postanovleniye ot 30 dekabrya 2021 goda No. 635-p [On measures to implement the state program of the Khanty-Mansiysk Autonomous Region–Ugra «Housing and communal services complex and urban environment»: Resolution of December 30, 2021, No. 635-p] // Pravitel’stvo Khanty-Mansiyskogo avtonomnogo okruga– Yugry. Government of the Khanty-Mansiysk Autonomous Region. 2021. 183 p. (In Russ.).

10. Bushin S. A., Kureynik V. V. Geneticheskiy algoritm razmeshcheniya raznogabaritnykh elementov [Different-dimension elements placement genetic algorithm] // Izvestiya YuFU. Tekhnicheskiye nauki. Izvestiya Sfedu. Engineering Sciences. 2009. No. 12 (101). P. 22–27. EDN: LAUDKZ. (In Russ.).

11. Ghorayeb K., Hayek H., Harb A. [et al.]. Bridging the integration gap — simultaneous optimization of well placement, well trajectory, and facility layout // Journal of Petroleum Science and Engineering. 2023. Vol. 220. P. 111222. DOI: 10.1016/j.petrol.2022.111222. (In Engl.).

12. Gadalov A. B., Kozlov E. G., Kosyakov S. V. Analiz stoimosti razmeshcheniya transformatornykh podstantsiy s ispol’zovaniyem metodov postroyeniya tsenovykh poverkhnostey v srede GIS [Power distribution substations locations analysis using the methods of constructing cost surfaces in GIS] // Sostoyaniye i perspektivy razvitiya elektro- i teplotekhnologii (XXI Benardosovskiye chteniya). State and Prospects for the Development of Electrical and Thermal Technology (XXI Benardos Readings). Ivanovo, 2021. Vol. 3. P. 9–12. EDN: FWUTYG. (In Russ.).

13. Afanas’yev A. P., Grinkrug M. S., Tkacheva Yu. I. Opredeleniye mestopolozheniya transformatornykh podstantsiy v seti elektrosnabzheniya nizkogo napryazheniya s pomoshch’yu kumulyativnoy matritsy geodezicheskikh distantsiy [Finding coordinates of transformer sustations in low voltage power supply network with the help of the cumulative matrix of geodesic distances] // Elektrotekhnika: Setevoy Elektronnyy Nauchnyy Zhurnal. Russian Internet Journal of Electrical Engineering. 2014. Vol. 1, no. 2. P. 17–20. EDN: SYETKT. (In Russ.).

14. Khomchenko V. G., Zuga I. M., Kuzhel’ A. N. Issledovaniye kachestvennykh pokazateley metodov trassirovki na osnove volnovogo algoritma i algoritma A* primenitel’no k promyshlennym predpriyatiyam [Qualitative research of routing methods based on wave algorithm and algorithm A* for industrial plants] // Omskiy Nauchnyy Vestnik. Omsk Scientific Bulletin. 2018. No. 6 (162). P. 220–224. DOI: 10.25206/1813-8225-2018-162-220-224. EDN: YSWONF. (In Russ.).

15. Zhila V. A., Klochko A. K., Markevich Yu. G. Nakhozhdeniye konfiguratsii gazoraspredelitel’nykh setey matematicheskimi metodami [Finding the configuration of gas distribution networks by mathematical methods] // Internet-Vestnik VolgGASU. Russian Internet Journal of Electrical Engineering. 2013. No. 1 (25). P. 1–4. EDN: RBBGHH. (In Russ.).

16. Novakovskiy B. A., Kargashin P. E., Karpachevskiy A. M. Geoinformatsionnyy analiz territorii dlya avtomatizirovannogo vybora trassy LEP [Gis-techniques application for automatic power line route selection] // Geoinformatika. Geoinformatika. 2017. No. 2. P. 30–38. EDN: ZRCUOB. (In Russ.).

17. Pravila ustroystva elektroustanovok [Rules for the installation of electrical installations]. Novosibirsk, 2005. 510 p. (In Russ.).

18. Rossiyskaya Federatsiya. Postanovleniye. O poryadke ustanovleniya okhrannykh zon ob”yektov elektrosetevogo khozyaystva i osobykh usloviy ispol’zovaniya zemel’nykh uchastkov, raspolozhennykh v granitsakh takikh zon: postanovleniye ot 24 fevralya 2009 g. No. 160 [Russian Federation. Resolution. On the procedure for establishing security zones of electric grid facilities and special conditions for the use of land plots located within the boundaries of such zones: Resolution of February 24, 2009 No. 160]. Available at «Consultant Plus» System. (In Russ.).

19. Kormen T. Kh., Leizerson C., Rivest R. [et al.]. Algoritmy: postroyeniye i analiz [Algorithms: construction and analysis]. Moscow, 2013. 1328 p. ISBN 978-5-8459-1794-2. (In Russ.).

20. GOST 32144-2013. Elektricheskaya energiya. Sovmestimost’ tekhnicheskikh sredstv elektromagnitnaya. Normy kachestva elektricheskoy energii v sistemakh elektrosnabzheniya obshchego naznacheniya [Electric energy. Electromagnetic compatibility of technical equipment. Power quality limits in the public power supply systems]. Moscow, 2014. 19 p. (In Russ.).

21. Rossiyskaya Federatsiya. Prikaz. Ob utverzhdenii ukrupnennykh normativov tseny tipovykh tekhnologicheskikh resheniy kapital’nogo stroitel’stva ob”yektov elektroenergetiki v chasti ob”yektov elektrosetevogo khozyaystva: prikaz ot 17 yanvarya 2019 g. No. 10 [Russian Federation. Order. On approval of consolidated price standards for standard technological solutions for capital construction of electric power facilities in terms of power grid facilities: order dated January 17, 2019 No. 10]. Available at «Consultant Plus» System. (In Russ.).