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Hierarchical Provision of Distribution Grid Flexibility with Online Feedback Optimization (2403.10315v1)

Published 15 Mar 2024 in eess.SY and cs.SY

Abstract: Utilizing distribution grid flexibility for ancillary services requires the coordination and dispatch of requested active and reactive power to a large number of distributed energy resources in underlying grid layers. This paper presents an approach to hierarchically dispatch flexibility requests based on Online Feedback Optimization (OFO). We implement a framework of individual controllers coordinating actors, contributing to flexibility provision, to track a requested operating point at the interface between grid layers. The framework is evaluated in terms of performance during coordination and possible interaction between individual controllers, both central and distributed. Results show high reliability and robustness of the OFO controllers as well as an efficient dispatch of active and reactive power. Its computational efficiency and capabilities in set point tracking during online grid operation are making OFO a promising approach to the flexibility dispatch problem.

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References (19)
  1. InnoSys 2030, “InnoSys 2030 – Innovations in System Operation up to 2030 - Short Report on the Joint Project.” Jun. 01, 2022. Accessed: Apr. 17, 2023. [Online]. Available: https://www.innosys2030.de/wp-content/uploads/InnoSys-ShortReport-EN.pdf
  2. T. Kolster, R. Krebs, S. Niessen, and M. Duckheim, “The contribution of distributed flexibility potentials to corrective transmission system operation for strongly renewable energy systems,” Applied Energy, vol. 279, p. 115870, Dec. 2020.
  3. T. Kolster, S. Niessen, and M. Duckheim, “Providing Distributed Flexibility for Curative Transmission System Operation Using a Scalable Robust Optimization Approach,” Electric Power Systems Research, Oct. 2022.
  4. V. Haberle, M. W. Fisher, E. Prieto-Araujo, and F. Dorfler, “Control Design of Dynamic Virtual Power Plants: An Adaptive Divide-and-Conquer Approach,” IEEE Trans. Power Syst., vol. 37, no. 5, pp. 4040–4053, Sep. 2022.
  5. S. Karagiannopoulos, J. Gallmann, M. G. Vaya, P. Aristidou, and G. Hug, “Active Distribution Grids Offering Ancillary Services in Islanded and Grid-Connected Mode,” IEEE Trans. Smart Grid, vol. 11, no. 1, pp. 623–633, Jan. 2020.
  6. S. Karagiannopoulos, C. Mylonas, P. Aristidou, and G. Hug, “Active Distribution Grids Providing Voltage Support: The Swiss Case,” IEEE Trans. Smart Grid, vol. 12, no. 1, pp. 268–278, Jan. 2021.
  7. T. Alazemi, M. Darwish, and M. Radi, “TSO/DSO Coordination for RES Integration: A Systematic Literature Review,” Energies, vol. 15, no. 19, p. 7312, Oct. 2022.
  8. M. Picallo, S. Bolognani, and F. Dörfler, “Closing the loop: Dynamic state estimation and feedback optimization of power grids,” Electric Power Systems Research, vol. 189, p. 106753, Dec. 2020.
  9. Kalantar-Neyestanaki and R. Cherkaoui, “Coordinating Distributed Energy Resources and Utility-Scale Battery Energy Storage System for Power Flexibility Provision Under Uncertainty,” IEEE Trans. Sustain. Energy, vol. 12, no. 4, pp. 1853–1863, Oct. 2021.
  10. D. A. Contreras, S. Muller, and K. Rudion, “Congestion Management Using Aggregated Flexibility at the TSO-DSO Interface,” in 2021 IEEE Madrid PowerTech, Madrid, Spain: IEEE, Jun. 2021, pp. 1–6.
  11. O. K. Olsen, D. Sieraszewski, D. Ivanko, I. Oleinikova, and H. Farahmand, “Hybrid AC/DC Optimal Power Flow Modelling Approach for Coordination in Flexibility Market,” in 2021 International Conference on Smart Energy Systems and Technologies (SEST), Vaasa, Finland: IEEE, Sep. 2021.
  12. H. Früh, S. Müller, D. Contreras, K. Rudion, A. Von Haken, and B. Surmann, “Coordinated Vertical Provision of Flexibility From Distribution Systems,” IEEE Trans. Power Syst., vol. 38, no. 2, pp. 1834–1844, Mar. 2023.
  13. A. Hauswirth, S. Bolognani, G. Hug, and F. Dörfler, “Optimization Algorithms as Robust Feedback Controllers.” arXiv, http://arxiv.org/abs/2103.11329, Mar. 21, 2021.
  14. S. Bolognani and F. Dorfler, “Fast power system analysis via implicit linearization of the power flow manifold,” in 2015 53rd Annual Allerton Conference on Communication, Control, and Computing (Allerton), Monticello, IL: IEEE, Sep. 2015, pp. 402–409.
  15. M. Picallo, L. Ortmann, S. Bolognani, and F. Dörfler, “Adaptive real-time grid operation via Online Feedback Optimization with sensitivity estimation,” Electric Power Systems Research, vol. 212, p. 108405, Nov. 2022.
  16. L. Ortmann, A. Hauswirth, I. Caduff, F. Dörfler, and S. Bolognani, “Experimental Validation of Feedback Optimization in Power Distribution Grids,” Electric Power Systems Research, vol. 189, p. 106782, Dec. 2020.
  17. L. Ortmann, G. Hotz, S. Bolognani, and F. Dörfler, “Real-time Curative Actions for Power Systems via Online Feedback Optimization.” IEEE 2023 Belgrad PowerTech, Belgrad, Serbia, 2023.
  18. L. Ortmann, F. Böhm, F. Klein-Helmkamp, A. Ulbig, S. Bolognani, and F. Dörfler, “Tuning and Testing an Online Feedback Optimization Controller to Provide Curative Distribution Grid Flexibility.” arXiv, 2024.
  19. “VDE-AR-N 4105: Generators connected to the LV distribution network – Technical requirements for the connection to and parallel operation with low-voltage distribution networks,” 2018.
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