Effect of Energy Storages on Flexibility and Cyber Resilience of Electric Networks

Irina Kolosok; Elena Korkina; Victor Kurbatsky

doi:10.1051/epjconf/201921701006

All issues

Volume 217 (2019)

EPJ Web Conf., 217 (2019) 01006

References

Open Access

Issue		EPJ Web Conf. Volume 217, 2019 International Workshop on Flexibility and Resiliency Problems of Electric Power Systems (FREPS 2019)


Article Number		01006
Number of page(s)		5
DOI		https://doi.org/10.1051/epjconf/201921701006
Published online		15 October 2019

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[1] https://ekoenergia.ru/o-probleme/vozobnovlyaemyie-istochniki-energii-v-rossii.html [Google Scholar]

[2] J. Сochran, M. Miller, O. Zinaman, M. Milligan, et al. Flexibility in 21st Century power systems // 21st Century Power Partnership, Denver,USA, Clean Energy Ministerial, (2014). [Google Scholar]

[3] E. Lannoye, D. Flynn, M. O’Malley. Evaluation of power system flexibility // IEEE Trans. Power Syst., 27, 2, (2012). [Google Scholar]

[4] U. Haeger, C. Rehtanz, N. Voropai. ICOEUR project results on improving observability and flexibility of large-scale transmission systems // IEEE PES General Meeting, San Diego, USA, (2012). [Google Scholar]

[5] A. Ulbig, G. Andersson. Analyzing operational flexibility of electric power systems // 18th PSCC, Wroclaw, Poland, ( 2014). [Google Scholar]

[6] Potapenko A.M., Melnikov V.D. Energy storage facilities in the electric power supply systems of industrial companies. http://estorsys.ru/publications/sistemy-nakopleniya-energii-v-sistemah [Google Scholar]

[7] Concept of developing the market of energy storage facilities in RF, (2017). https://minenergo.gov.ru/node/9013 [Google Scholar]

[8] Z. Wang, M.S. Nistor, S.W. Pickl. Analysis of the definitions of resilience // The 20th IFAC World Congress, Toulouse, France, (2017). [Google Scholar]

[9] C. Nan, G. Sansavini, W. Kroeger. Building an integrated metric for quantifying the resilience of interdependent infrastructure systems // 9th Intern. Conf. on Critical Information Infrastructure Security, Limassol, Cyprus, (2014). [Google Scholar]

[10] Massoud A. Challenges in reliability, security, efficiency, and resilience of energy infrastructure: Toward smart self-healing electric power grid // IEEE PES General Meeting, Pittsburg, USA, (2008). [Google Scholar]

[11] N. Voropai, I. Kolosok, E. Korkina, A. Osak. Transformation of properties of future energy systems and problems of ensuring their steady-state operation. Baku, (2018). [Google Scholar]

[12] Yu. Kulikov. Electric energy storages as an efficient tool for managing the operating conditions of electric power systems. [Google Scholar]

[13] N. Novikov, A. Novikov. Prospects of using the energy storage and intelligent management systems for distributed generation with involvement of renewable energy sources. OJSC NTC FSK EES, (2012). [Google Scholar]

[14] K. Heussen, S. Koch, A. Ulbig, G. Andersson Unified System-Level Modeling of Intermittent Renewable Energy Sources and Energy Storage for Power System Operation // 140 IEEE Systems Journal, 6, 1, (2012). [CrossRef] [Google Scholar]

[15] M.A. Bucher, S. Delikaraoglou, K. Heussen, P. Pinson, G. Andersson. On quantification of flexibility in power systems, IEEE PowerTech, Eindhoven, Netherlands, (2015). [Google Scholar]

[16] N. Voropai, I. Kolosok, E. Korkina, A. Osak. Problems of vulnerability and survivability of cyber-physical and electric power systems // Energy Policy, 5, (2018). [Google Scholar]

[17] N. Voropai. EPS Survivability: Methodological grounds and methods of studies // Izv. AN SSSR. Energy and transport, 6, (1991). [Google Scholar]

[18] A. Diakov, V. Stennikov, S. Senderov, M. Sukharev et al. Reliability of energy systems: Problems, models and methods of their solution (Editor N. I. Voropai. Novosibirsk: Nauka, 2014). [Google Scholar]

[19] V. Stroev, A. Gremiakov, C. Arachchige, Z. Styczynski. Optimal Allocation of Energy Storage devices in electrical power systems. 13-th PSCC in Trondheim, (1999) [Google Scholar]