Application of Digital Technologies for Expansion Planning of Integrated Energy Systems
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- References 1. M. Geidl , IEEE Transactions on Power Systems, 22
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Creation on the basis of several separately functioning mono-systems (electricity, heat/cool, gas supply and others) of a new energy technology structure in the form of an integrated energy system significantly expands their functional capabilities, ensures the interchangeability of energy carriers and implements a synergistic effect to ensure reliable, safe, economical and environmentally friendly energy supply. The technological transformation of energy systems becomes possible due to the active development of modern digital technologies, telecommunications and information systems and their interpenetration, which allows the formation of flexible intelligent expansion planning and operation control of IESs, the coordination of individual subsystems and the implementation of system-wide Fig. 2. Architecture of an information and communication platform for integrated energy systems research. E3S Web of Conferences 209 , 02003 (2020) ENERGY-21 https://doi.org/10.1051/e3sconf/202020902003 4 targets. This leads to the emergence of new tasks of control of such systems and the need to develop methods for their solution, to study of properties, trends and features of development. The work was carried out within framework of scientific project III.17.4.1 (No. АААА-А17-117030310432-9) of the program of fundamental research of the Siberian Branch of the Russian Academy of Sciences. References 1. M. Geidl , IEEE Transactions on Power Systems, 22 , 145-155 (2007) 2. A. Vasebi, M. Fesanghary, M.T. Bathaee, Electrical Power and Energy Systems, 29 , 713-719 (2007) 3. Z. Li, Z. Huo, H. Yin, Asia-Pacific Power and Energy Engineering Conference (IEEE, Wuhan, 2011) 4. N.I. Voropai, V.A. Stennikov, Izvestiya RAN. Energetika, 64-73, (2014) (in Russian) 5. M. Geidl, G. Andersson, European Transactions on Electrical Power, 16 , 463-477 (2006) 6. M. Geidl, G. Koeppel, P. Favre-Perrod, B. Klockl, G. Andersson, K. Frohlich, IEEE Power and Energy Magazine, 5, 24-30 (2007) 7. M. Almassalkhi, I. Hiskens, 17th Power System Computation Conference (Stockholm, 2011) 8. N.I. Voropai, V.A. Stennikov, E.A. Barakhtenko, O.N. Voitov, I.V. Postnikov, Energy Systems Research, 1 , 57-66 (2018) 9. J. Momoh, Smart Grid: Fundamentals of design and analysis (2012) 10. S. Le Blond, T. Lewis, M. Sooriyabandara, 2nd IEEE PES International Conference and Exhibition on Innovative Smart Grid Technologies (IEEE, Manchester, 2011) 11. P. Mancarela, Chin Kim Gan, G. Strbac, 17th Power System Computation Conference (Stockolm, 2011) 12. N.I. Voropai, E.V. Ukolova, D.O. Gerasimov, K.V. Suslov, P. Lombardi, P. Komarnicki, Vestnik IrGTU, 22 , 157-168 (2018) (in Russian) 13. I. van Beuzekom, M. Gibescu, J.G. Slootweg, 2015 IEEE Eindhoven PowerTech (IEEE, Eindhoven, 2015) 14. R. Bent, S. Blumsack, P. Van Hentenryck, C. Borraz- Sánchez, M. Shahriari, IEEE Transactions on Power Systems, Yüklə 2,01 Mb. Dostları ilə paylaş:
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