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Unlocking Energy Flexibility From Thermal Inertia of Buildings: A Robust Optimization Approach (2312.05108v1)

Published 8 Dec 2023 in eess.SY and cs.SY

Abstract: Towards integrating renewable electricity generation sources into the grid, an important facilitator is the energy flexibility provided by buildings' thermal inertia. Most of the existing research follows a single-step price- or incentive-based scheme for unlocking the flexibility potential of buildings. In contrast, this paper proposes a novel two-step design approach for better harnessing buildings' energy flexibility. In a first step, a robust optimization model is formulated for assessing the energy flexibility of buildings in the presence of uncertain predictions of external conditions, such as ambient temperature, solar irradiation, etc. In a second step, energy flexibility is activated in response to a feasible demand response (DR) request from grid operators without violating indoor temperature constraints, even in the presence of uncertain external conditions. The proposed approach is tested on a high-fidelity Modelica simulator to evaluate its effectiveness. Simulation results show that, compared with price-based demand-side management, the proposed approach achieves greater energy reduction during peak hours.

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References (25)
  1. European Commission, Directorate General for Energy, “Clean energy for all europeans package,” 2019. [Online]. Available: https://energy.ec.europa.eu/topics/energy-strategy/clean-energy-all-europeans-package˙en
  2. L. Pérez-Lombard, J. Ortiz, and C. Pout, “A review on buildings energy consumption information,” Energy and Buildings, vol. 40, no. 3, pp. 394–398, 2008.
  3. G. Bianchini, M. Casini, A. Vicino, and D. Zarrilli, “Demand-response in building heating systems: A model predictive control approach,” Applied Energy, vol. 168, pp. 159–170, 2016.
  4. EPBD-III, “Directive of the european parliament and of the council on the energy performance of buildings (recast),” 2021. [Online]. Available: https://eur-lex.europa.eu/resource.html?uri=cellar:c51fe6d1-5da2-11ec-9c6c-01aa75ed71a1.0001.02/DOC˙1&format=PDF
  5. H. Golmohamadi, K. G. Larsen, P. G. Jensen, and I. R. Hasrat, “Optimization of power-to-heat flexibility for residential buildings in response to day-ahead electricity price,” Energy and Buildings, vol. 232, p. 110665, 2021.
  6. ——, “Integration of flexibility potentials of district heating systems into electricity markets: A review,” Renewable and Sustainable Energy Reviews, vol. 159, p. 112200, 2022.
  7. A. Vandermeulen, B. van der Heijde, and L. Helsen, “Controlling district heating and cooling networks to unlock flexibility: A review,” Energy, vol. 151, pp. 103–115, 2018.
  8. J. Kensby, A. Trüschel, and J.-O. Dalenbäck, “Potential of residential buildings as thermal energy storage in district heating systems–results from a pilot test,” Applied Energy, vol. 137, pp. 773–781, 2015.
  9. F. Oldewurtel, D. Sturzenegger, G. Andersson, M. Morari, and R. S. Smith, “Towards a standardized building assessment for demand response,” in 52nd IEEE Conference on Decision and Control.   IEEE, 2013, pp. 7083–7088.
  10. F. D’Ettorre, M. De Rosa, P. Conti, D. Testi, and D. Finn, “Mapping the energy flexibility potential of single buildings equipped with optimally-controlled heat pump, gas boilers and thermal storage,” Sustainable Cities and Society, vol. 50, p. 101689, 2019.
  11. C. Wu, W. Gu, Y. Xu, P. Jiang, S. Lu, and B. Zhao, “Bi-level optimization model for integrated energy system considering the thermal comfort of heat customers,” Applied Energy, vol. 232, pp. 607–616, 2018.
  12. Z. Pan, Q. Guo, and H. Sun, “Feasible region method based integrated heat and electricity dispatch considering building thermal inertia,” Applied Energy, vol. 192, pp. 395–407, 2017.
  13. E. Vrettos, F. Oldewurtel, and G. Andersson, “Robust energy-constrained frequency reserves from aggregations of commercial buildings,” IEEE Transactions on Power Systems, vol. 31, no. 6, pp. 4272–4285, 2016.
  14. F. A. Qureshi and C. N. Jones, “Hierarchical control of building hvac system for ancillary services provision,” Energy and Buildings, vol. 169, pp. 216–227, 2018.
  15. T. T. Gorecki, L. Fabietti, F. A. Qureshi, and C. N. Jones, “Experimental demonstration of buildings providing frequency regulation services in the swiss market,” Energy and Buildings, vol. 144, pp. 229–240, 2017.
  16. X. Zhang, G. Schildbach, D. Sturzenegger, and M. Morari, “Scenario-based MPC for energy-efficient building climate control under weather and occupancy uncertainty,” in 2013 European Control Conference (ECC).   IEEE, 2013, pp. 1029–1034.
  17. M. Ostadijafari and A. Dubey, “Tube-based model predictive controller for building’s heating ventilation and air conditioning (HVAC) system,” IEEE Systems Journal, 2020.
  18. J. Shi, Y. Lian, and C. N. Jones, “Robust learning model predictive control for periodically correlated building control,” in 2021 European Control Conference (ECC).   IEEE, 2021, pp. 192–197.
  19. P. Bacher and H. Madsen, “Identifying suitable models for the heat dynamics of buildings,” Energy and Buildings, vol. 43, no. 7, pp. 1511–1522, 2011.
  20. H. Madsen, P. Bacher, G. Bauwens, A.-H. Deconinck, G. Reynders, S. Roels, E. Himpe, and G. Lethé, “Thermal performance characterization using time series data-iea ebc annex 58 guidelines,” 2015.
  21. A. Parsi, P. Anagnostaras, A. Iannelli, and R. S. Smith, “Computationally efficient robust MPC using optimized constraint tightening,” in 2022 IEEE 61st Conference on Decision and Control (CDC).   IEEE, 2022, pp. 1770–1775.
  22. Report of Annex67, “Modelling of possible energy flexibility in single buildings and building clusters,” 2019. [Online]. Available: https://www.annex67.org/media/1866/modelling-of-possible-energy-flexibility.pdf
  23. X. Zhang, M. Kamgarpour, A. Georghiou, P. Goulart, and J. Lygeros, “Robust optimal control with adjustable uncertainty sets,” Automatica, vol. 75, pp. 249–259, 2017.
  24. P. Scharnhorst, B. Schubnel, C. Fernández Bandera, J. Salom, P. Taddeo, M. Boegli, T. Gorecki, Y. Stauffer, A. Peppas, and C. Politi, “Energym: A building model library for controller benchmarking,” Applied Sciences, vol. 11, no. 8, p. 3518, 2021.
  25. G. C. Mouli, P. Bauer, and M. Zeman, “System design for a solar powered electric vehicle charging station for workplaces,” Applied Energy, vol. 168, pp. 434–443, 2016.
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