ADDITIONAL DAMPING TORQUE CONTROL OF DFIG-BASED WIND TURBINE CONSIDERING THE THREE-MASS SHAFT MODEL, 245-251.

Suxiang Yang∗ and Haoming Liu∗

References

1. [1] S. Huang, Q. Wu, W. Bao, N.D. Hatziargyriou, L. Ding, andF. Rong, Hierarchical optimal control for synthetic inertialresponse of wind farm based on alternating direction method ofmultipliers, IEEE Transactions on Sustainable Energy, 12(1),2021, 25–35.
2. [2] N. Gurung, R. Bhattarai, and S. Kamalasadan, Optimal os-cillation damping controller design for large-scale wind inte-grated power grid, IEEE Transactions on Industry Applica-tions, 56(4), 2020, 4225–4235.
3. [3] T. Jain and J.J. Yame, Fault-tolerant economic model predic-tive control for wind turbines, IEEE Transactions on Sustain-able Energy, 10(4), 2019, 1696–1704.
4. [4] S.L. Zhang, C.C. Zhu, C.S. Song, J.J. Tan, and X. Chen,Natural characteristic analysis of wind turbine drivetrain con-sidering flexible supporting, Proceedings of the Institution ofMechanical Engineers, Part C: Journal of Mechanical Engi-neering Science, 232(5), 2018, 842–856.
5. [5] D. Xie, J. Sun, Y. Lu, et al., Torsional vibration characteristicsanalysis of DFIG-based wind farm and its equivalent model,IEEJ Transactions on Electrical and Electronic Engineering,12(5), 2017, 646–656.
6. [6] Z. Li, T. Zhang, Y. Chen, and L. Song, The effect of parallel-axis helix gear pair on wind turbine gearbox vibration control,Shock and Vibration, 2020, 2020, 1–13.
7. [7] R. Barcena, T. Acosta, A. Etxebarria, and I. Kortabarria,LIDAR-assisted wind turbine structural load reduction bylinear single model predictive control, IEEE Access, 8, 2020,146548–146559.
8. [8] R.K. Varma, S. Auddy, and Y. Semsedini, Mitigation of sub-synchronous resonance in a series-compensated wind farm us-ing FACTS controllers, IEEE Transactions on Power Delivery,23(3), 2008, 1645–1654.
9. [9] H. Geng, X. Xi, L. Liu, et al., Hybrid modulated activedamping control for DFIG-based wind farm participating infrequency response, IEEE Transactions on Energy Conversion,32(3), 2017, 1220–1230.
10. [10] M. Rahimi, Improvement of energy conversion efficiency anddamping of wind turbine response in grid connected DFIGbased wind turbines, International Journal of Electrical Power& Energy Systems, 95, 2018, 11–25.
11. [11] Z.Y. Li, S.J. Tian, Y.F. Zhang, H. Li, and M. Lu, Activecontrol of drive chain torsional vibration for DFIG-based windturbine, Energies, 12(9), 2019, 1–16.
12. [12] S. Tian, Z. Li, H. Li, Y. Hu, and M. Lu, Active control methodfor torsional vibration of DFIG drive chain under asymmetricpower grid fault, IEEE Access, 8, 2020, 155611–155618.
13. [13] L. Sun, K. Liu, J. Hu, and Y. Hou, Analysis and mitigation ofelectromechanical oscillations for DFIG wind turbines involvedin fast frequency response, IEEE Transactions on PowerSystems, 34(6), 2019, 4547–4556.
14. [14] F. Fateh, W.N. White, and D. Gruenbacher, Torsional vibra-tions mitigation in the drivetrain of DFIG-based grid-connectedwind turbine, IEEE Transactions on Industry Applications,53(6), 2017, 5760–5767.
15. [15] J.K. Kambrath, M.S.U. Khan, Y. Wang, et al., A novel controltechnique to reduce the effects of torsional interaction in windturbine system, IEEE Journal of Emerging and Selected Topicsin Power Electronics, 7(3), 2019, 2090–2105.
16. [16] G. Mandic, A. Nasiri, E. Muljadi, and F. Oyague, Activetorque control for gearbox load reduction in a variable-speedwind turbine, IEEE Transactions on Industry Applications,48(6), 2012, 2424–2432.
17. [17] J. Licari, C.E. Ugalde-Loo, J.B. Ekanayake, and N. Jenkins,Damping of torsional vibrations in a variable-speed wind tur-bine, IEEE Transactions on Energy Conversion, 28(1), 2013,172–180.
18. [18] L. Liu and D. Xie, Performance comparison of two differentfilter design approaches for torsional vibration damping in adoubly fed induction generator-based wind turbine, Journal ofEngineering, 2015(6), 2015, 197–204.
19. [19] L. Liu, D. Xie, H. Chu, and C. Gu, A damping method fortorsional vibrations in a DFIG wind turbine system based onsmall-signal analysis, Electric Power Components and Systems,45(5), 2017, 560–573.
20. [20] S.M. Muyeen, M.H. Ali, et al., Transient stability analysisof grid connected wind turbine generator system consideringmulti-mass shaft modeling, Electric Power Components andSystems, 34(10), 2006, 1121–1138.
21. [21] T. Ackermann (ed.), Wind power in power systems, 1st ed.(Chichester: John Wiley & Sons, Ltd., 2005).
22. [22] Z. Chen, L. Zheng, G. Qiang, et al., Damping effects ontorsional oscillation of DFIG drive-chain using different controlstrategies, Proceedings of the CSEE, 33(27), 2013, 135–144.
23. [23] L.A. Kilgore, D.G. Ramey, and M.C. Hall, Simplified trans-mission and generation system analysis procedures for subsyn-chronous resonance problems, IEEE Transactions on PowerApparatus and Systems, 96(6), 1977, 1840–1846.
24. [24] M. Yu, N. Feng, and E.J. Hahn, An equation decouplingapproach to identify the equivalent foundation in rotatingmachinery using modal parameters, Journal of Sound andVibration, 365, 2016, 182–198.
25. [25] G. Xu, C. Zhu, T. Bi, A. Xue, and J. Hu, Optimal frequencycontroller parameters of wind turbines participating systemfrequency control, Proc. 2018 IEEE Power & Energy SocietyGeneral Meeting, Portland, USA, 2018, 1–5.

Important Links:

• Abstract
• DOI: 10.2316/J.2021.203-0366
• From Journal (203) International Journal of Power and Energy Systems - 2021

Go Back