DISCRETE PREDICTIVE CONTROL OF A FLYWHEEL ENERGY STORAGE FOR TRANSIENT STABILITY AUGMENTATION

Hailiya Ahsan and Mairaj ud Din Mufti

References

  1. [1] W. Gao, A. Darvishan, M. Toghani, M. Mohammadi, O. Abedinia, and N. Ghadimi, Different states of multi-block based forecast engine for price and load prediction, International Journal of Electrical Power & Energy Systems, 104, 2019, 423–435.
  2. [2] O. Abedinia, M. Zareinejad, M.H. Doranehgard, G. Fathi, and N. Ghadimi, Optimal offering and bidding strategies of renewable energy based large consumer using a novel hybrid robust-stochastic approach, Journal of Cleaner Production, 215, 2019, 878–889.
  3. [3] S. Vazquez, S.M. Lukic, E. Galvan, L.G. Franquelo, and J.M. Carrasco, Energy storage systems for transport and grid applications, IEEE Transactions on Industrial Electronics, 57(12), 2010, 3881–3895.
  4. [4] H.A. Bagal, Y.N. Soltanabad, M. Dadjuo, K. Wakil, and N. Ghadimi, Risk-assessment of photovoltaic-wind-battery-grid based large industrial consumer using information gap decision theory, Solar Energy, 169, 2018, 343–352.
  5. [5] H. Ahsan and M.-D. Mufti, Modelling and stability investigations of an aggregate wind farm-fed multi-machine system, Wind Engineering, 2019, https://doi.org/10.1177/ 0309524X19862759.
  6. [6] J. Slootweg and W. Kling, Modeling of large wind farms in power system simulations, IEEE Power Engineering Society Summer Meeting, Chicago, IL, 2002, 503–508.
  7. [7] S. Muller, M. Deicke, and R.W. De Doncker, Doubly fed induction generator systems for wind turbines, IEEE Industry Applications Magazine, 8(3), 2002, 26–33.
  8. [8] L. Wang and D.-N. Truong, Stability enhancement of DFIG- based offshore wind farm fed to a multi-machine system using a STATCOM, IEEE Transactions on Power Systems, 28(3), 2013, 2882–2889.
  9. [9] S.R. Gurumurthy, V. Agarwal, and A. Sharma, Optimal energy harvesting from a high-speed brushless dc generator-based flywheel energy storage system, IET Electric Power Applications, 7(9), 2013, 693–700.
  10. [10] J.-D. Park, C. Kalev, and H.F. Hofmann, Control of high- speed solid-rotor synchronous reluctance motor/generator for flywheel-based uninterruptible power supplies, IEEE Transactions on Industrial Electronics, 55 (8), 2008, 3038–3046.
  11. [11] R. Sebasti´an and R.P. Alzola, Flywheel energy storage systems: Review and simulation for an isolated wind power system, Renewable and Sustainable Energy Reviews, 16(9), 2012, 6803–6813.
  12. [12] G. Suvire and P. Mercado, Active power control of a flywheel energy storage system for wind energy applications, IET Renewable Power Generation, 6(1), 2012, 9–16.
  13. [13] T.A. Taj, H.M. Hasanien, A.I. Alolah, and S.M. Muyeen, Transient stability enhancement of a grid-connected wind farm using an adaptive neuro-fuzzy controlled-flywheel energy storage system, IET Renewable Power Generation, 9(7), 2015, 792–800.
  14. [14] S. Chaouch and M.-S. Nait-Said, Backstepping control design for position and speed tracking of dc motors, Asian Journal of Information Technology, 5(12), 2006, 1367–1372.
  15. [15] H. Silva-Saravia, H. Pulgar-Painemal, and J.M. Mauricio, Fly- wheel energy storage model, control and location for improving stability: The Chilean case, IEEE Transactions on Power Systems, 32(4), 2016, 3111–3119.
  16. [16] H. Ahsan and M.D. Mufti, Dynamic performance improvement of a hybrid multimachine system using a flywheel energy storage system, Wind Engineering, 2019, https://doi.org/10.1177/0309524X19849853.
  17. [17] L. Ran, D. Xiang, and J.L. Kirtley, Analysis of electromechanical interactions in a flywheel system with a doubly fed induction machine, IEEE Transactions on Industry Applications, 47(3), 2011, 1498–1506.
  18. [18] F. Diaz-Gonzalez, F.D. Bianchi, A. Sumper, and O. Gomis- Bellmunt, Control of a flywheel energy storage system for power smoothing in wind power plants, IEEE Transactions on Energy Conversion, 29(1), 2013, 204–214.
  19. [19] M.Y. Zargar, M.U.-D. Mufti, and S.A. Lone, Adaptive predictive control of a small capacity SMES unit for improved frequency control of a wind-diesel power system, IET Renewable Power Generation, 11(14), 2017, 1832–1840.
  20. [20] Y. Mishra, S. Mishra, M. Tripathy, N. Senroy, and Z. Dong, Improving stability of a DFIG-based wind power system with tuned damping controller, IEEE Transactions on Energy Conversion, 24(3), 2009, 650–660.
  21. [21] F. Faraji, A. Majazi, K. Al-Haddad, et al., A comprehensive review of flywheel energy storage system technology, Renewable and Sustainable Energy Reviews, 67, 2017, 477–490.
  22. [22] D.B. Eisenhaure, J.L. Kirtley Jr, and L.E. Lesster, Uninterruptible power supply system using a slip-ring, wound-rotor- type induction machine and a method for flywheel energy storage, US Patent 7,071,581, 2006.
  23. [23] H. Ahsan and M. Mufti, Distributed storage approach versus singular storage approach: A dynamic stability evaluation, International Journal of Power and Energy Systems, 39(1), 2019.
  24. [24] N. Ghadimi, A. Akbarimajd, H. Shayeghi, and O. Abedinia, Two stage forecast engine with feature selection technique and improved meta-heuristic algorithm for electricity load forecasting, Energy, 161, 2018, 130–142.
  25. [25] C.L. Phillips and H.T. Nagle, Digital control system analysis and design (Englewood Cliffs, NJ: Prentice Hall, 2007).
  26. [26] H. Ahsan, Z. Salam, S.A. Lone, et al., Modeling and simulation of an energy storage based multi-machine power system for transient stability study, 2017 IEEE Conf. on Energy Conversion (CENCON), Kuala Lumpur, Malaysia, 2017, 78–83.
  27. [27] H. Ahsan, et al., Modeling and simulation of a superconducting magnetic energy storage based multi-machine power system for transient stability study, 2017 6th Int. Conf. on Computer Applications in Electrical Engineering-Recent Advances (CERA), Roorkee, India, 2017, 347–352.
  28. [28] P. Kundur, N.J. Balu, and M.G. Lauby, Power system stability and control, vol. 7 (NY: McGraw-Hill, 1994).
  29. [29] C. Nichita, D. Luca, B. Dakyo, and E. Ceanga, Large band simulation of the wind speed for real time wind turbine simulators, IEEE Transactions on Energy Conversion, 17(4), 2002, 523–529.
  30. [30] P.M. Anderson and A.A. Fouad, Power system control and stability (NY: John Wiley & Sons, 2008).

Important Links:

Go Back