Open Access
E3S Web Conf.
Volume 231, 2021
2020 2nd International Conference on Power, Energy and Electrical Engineering (PEEE 2020)
Article Number 01002
Number of page(s) 5
Section Power Engineering and Power Electronic Technology
Published online 25 January 2021
  1. D. Thomas, M. Iain, G. Dale, CIRED-Open Access Proceedings Journal, Virtual power plants leveraging energy flexibility in regional markets, 1, 2939-2943 (2017) [Google Scholar]
  2. S. Minniti, N. Haque, P. Nguyen, G. Pemen, Energies, Local markets for flexibility trading: Key stages and enablers, 11, 3074 (2018) [Google Scholar]
  3. P. Olivella-Rosell, E. Bullich-Massagué, M. Aragüés-Peñalba, A. Sumper, S.O. Ottesen, A.J. Vidal-Clos, R. Villafáfila-Robles, Applied energy, Optimization problem for meeting distribution system operator requests in local flexibility markets with distributed energy resources, 210, 881-895. (2018) [Google Scholar]
  4. J. Radecke, J. Hefele, L. Hirth,, Markets for Local Flexibility in Distribution Networks. (2019). [Google Scholar]
  5. S.S. Torbaghan, N. Blaauwbroek, P. Nguyen, M. Gibescu, IEEE 13TH International conference on the European Energy Market (EEM), Porto, Portugal, 16 (2016) [Google Scholar]
  6. Y. Li, W. Gao, Y. Ruan, Sustainable cities and society, Feasibility of virtual power plants (VPPs) and its efficiency assessment through benefiting both the supply and demand sides in Chongming country, China, 35, 544-551(2017) [Google Scholar]
  7. K. Dietrich, L.M. Latorre, L. Olmos, A. Ramos, Electric Power Systems Research, Modelling and assessing the impacts of self-supply and marketrevenue driven Virtual Power Plants, 119, 462-470(2015) [Google Scholar]
  8. X. Jin, Q. Wu, H. Jia, Applied Energy, Local flexibility markets: Literature review on concepts, models and clearing methods, 261, 114387 (2020) [Google Scholar]
  9. H. Steiniger, In Innovation and Disruption at the Grid’s Edge, Virtual Power Plants: Bringing the Flexibility of Decentralized Loads and Generation to Power Markets Academic Press, 331-362(2017) [Google Scholar]
  10. P. Olivella-Rosell, F. Rullan, P. Lloret-Gallego, E. Prieto-Araujo, R. Ferrer-San-José, S. Barja-Martinez, S.O. Ottesen, IEEE Transactions on Smart Grid, Centralised and Distributed Optimization for Aggregated Flexibility Services Provision, 11, 3257-3269 (2020) [Google Scholar]
  11. Z. Ullah, G. Mokryani, F. Campean, F.Y. Hu, IET Energy Systems Integration, Comprehensive review of VPPs planning, operation and scheduling considering the uncertainties related to renewable energy sources. 1, 147-157(2019) [Google Scholar]
  12. W.S. Sakr, H.A. Abdel-Ghany, R.A. EL-Sehiemy, A.M. Azmy, Alexandria Engineering Journal, Techno-economic assessment of consumers’ participation in the demand response program for optimal day-ahead scheduling of virtual power plants. 59, 399-415(2020) [Google Scholar]
  13. L.F. van Summeren, A.J. Wieczorek, G.J. Bombaerts, G.P. Verbong, Energy Research & Social Science, Community energy meets smart grids: Reviewing goals, structure, and roles in Virtual Power Plants in Ireland, Belgium and the Netherlands, 63, 101-415 (2020) [Google Scholar]
  14. D. Chattopadhyay, IEEE Transactions on Power Systems, Application of general algebraic modeling system to power system optimization, 15-22. (1999). [Google Scholar]

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