Normally, electrical and mechanical systems are designed and analysed in separate domains but, in this study, interactions between electric and mechanical elements are analysed looking for improvement in the performance of electromechanical drivetrains. The work considers a doubly fed induction generator, evaluated with a frequency analysis of the full electromechanical drivetrain developed and applied to identify how tuning gains and system parameters affect the electromechanical interactions. Analytical transfer functions are presented and validated by simulation and test results.

References

1. 1)
  - 14. Nian, H., Wang, T., Zhu, Z.Q.: ‘Voltage imbalance compensation for doubly fed induction generator using direct resonant feedback regulator’, IEEE Trans. Energy Convers., 2016, 31, (2), pp. 614–626.
2. 2)
  - 24. Ohm, D.Y.: ‘Analysis of PID and PDF compensators for motion control systems’. IEEE Industry Applications Society Annual Meeting, Denver, CO, USA, vol. 3, 1994, pp. 1923–1929.
3. 3)
  - 20. Feehally, T., Erazo-Damián, I., Apsley, J.M.: ‘Analysis of electromechanical interaction in aircraft generator systems’, IEEE Trans. Ind. Appl., 2016, 52, pp. 4327–4336.
4. 4)
  - 6. Lopes, L.A., Lhuilier, J., Khokar, M.F., et al: ‘A wind turbine emulator that represents the dynamics of the wind turbine rotor and drive train’. 2005 IEEE 36th Power Electronics Specialists Conf., Recife, Brazil, 2005, pp. 2092–2097.
5. 5)
  - 12. Feehally, T., Apsley, J.M.: ‘The doubly fed induction machine as an aero generator’, IEEE Trans. Ind. Appl., 2015, 51, pp. 3462–3471.
6. 6)
  - 10. Pena, R., Clare, J.C., Asher, G.M.: ‘A doubly fed induction generator using back-to-back PWM converters supplying an isolated load from a variable speed wind turbine’, IEE Proc. Electr. Power Appl., 1996, 143, pp. 380–387.
7. 7)
  - 22. Krause, P.C., Wasynczuk, O., Sudhoff, S.D., et al: ‘Analysis of electric machinery and drive systems’ (IEEE press, NJ, 2002), pp. 150–151.
8. 8)
  - 11. Carrasco, G., Silva, C.A., Peña, R., et al: ‘Control of a four-leg converter for the operation of a DFIG feeding stand-alone unbalanced loads’, IEEE Trans. Ind. Electron., 2015, 62, pp. 4630–4640.
9. 9)
  - 19. Valenzuela, M.A., Bentley, J.M., Villablanca, A., et al: ‘Dynamic compensation of torsional oscillation in paper machine sections’, IEEE Trans. Ind. Appl., 2005, 41, pp. 1458–1466.
10. 10)
  - 8. Cardenas, R., Pena, R., Alepuz, S., et al: ‘Overview of control systems for the operation of DFIGs in wind energy applications’, IEEE Trans. Ind. Electron., 2013, 60, pp. 2776–2798.
11. 11)
  - 26. Djurovic, S., Williamson, S.: ‘Losses and pulsating torques in DFIGs with unbalanced stator and rotor excitation’. 2008 IEEE Int. Conf. Sustainable Energy Technologies, Singapore, 2008, pp. 328–333.
12. 12)
  - 15. Xu, H., Hu, J., He, Y.: ‘Operation of wind-turbine-driven DFIG systems under distorted grid voltage conditions: analysis and experimental validations’, IEEE Trans. Power Electron., 2012, 27, (5), pp. 2354–2366.
13. 13)
  - 7. Singh, M., Muljadi, E., Jonkman, J.: ‘Hybrid electro-mechanical simulation tool for wind turbine generators’. 2013 IEEE Green Technologies Conf., Denver, CO, USA, 2013, pp. 266–270.
14. 14)
  - 4. Sarlioglu, B., Morris, C.T.: ‘More electric aircraft: review, challenges, and opportunities for commercial transport aircraft’, IEEE Trans. Transport. Electrif., 2015, 1, pp. 54–64.
15. 15)
  - 5. Mei, F., Pal, B.: ‘Modal analysis of grid-connected doubly fed induction generators’, IEEE Trans. Energy Convers., 2007, 22, pp. 728–736.
16. 16)
  - 1. Wachel, J.C.: ‘Analysis of torsional vibrations in rotating machinery’. Proc. Twenty-Second Turbomachinery Symp., San Antonio, Texas, USA, 1993.
17. 17)
  - 13. Geng, H., Liu, C., Yang, G.: ‘LVRT capability of DFIG-based WECS under asymmetrical grid fault condition’, IEEE Trans. Ind. Electron., 2013, 60, (6), pp. 2495–2509.
18. 18)
  - 25. Zigmund, B., Terlizzi, A.A., d, X., et al: ‘Experimental evaluation of PI tuning techniques for field oriented control of permanent magnet synchronous motors’, Adv. Electr. Electron. Eng., 2011, 5, pp. 114–119.
19. 19)
  - 23. Cheng, S., Huang, Y.-Y., Chou, H.-H., et al: ‘PDFF and H∞ controller design for PMSM drive’, in Sobh, T., Elleithy, K., Mahmood, A., Karim, M.A. (Eds.): ‘Novel algorithms and techniques in telecommunications automation and industrial electronics’ (Springer Netherlands, Dordrecht, 2008), pp. 237–241.
20. 20)
  - 16. Ahumada, C., Garvey, S., Yang, T., et al: ‘The importance of load pulse timing in aircraft generation’. 18th Int. Conf. Electrical Machines and Systems, Pattaya City, Thailand, 2015.
21. 21)
  - 21. Feehally, T.: ‘Electro-mechanical interaction in gas turbine-generator systems for more-electric aircraft’. PhD thesis, School of Electrical and Electronic Engineering, University of Manchester, Manchester, 2012.
22. 22)
  - 2. Ran, L., Xiang, D., Kirtley, J.L.: ‘Analysis of electromechanical interactions in a flywheel system with a doubly fed induction machine’, IEEE Trans. Ind. Appl., 2011, 47, pp. 1498–1506.
23. 23)
  - 3. Wheeler, P., Bozhko, S.: ‘The more electric aircraft: technology and challenges’, IEEE Electrif. Mag., 2014, 2, pp. 6–12.
24. 24)
  - 9. Pena, R., Clare, J.C., Asher, G.M.: ‘Doubly fed induction generator using back-to-back PWM converters and its application to variable-speed wind-energy generation’, IEE Proc. Electr. Power Appl., 1996, 143, pp. 231–241.
25. 25)
  - 17. Breslan, D.J., Apsley, J.M., Smith, A.C., et al: ‘Control of a vertical axis wind turbine in gusty conditions’. 8th IET Int. Conf. Power Electronics, Machines and Drives (PEMD 2016), Glasgow, UK, 2016, pp. 1–6.
26. 26)
  - 18. Prajapat, G.P., Senroy, N., Kar, I.N.: ‘Wind turbine structural modeling consideration for dynamic studies of DFIG based system’, IEEE Trans. Sustain. Energy, 2017, 8, pp. 1463–1472.

Electromechanical interactions in a doubly fed induction generator drivetrain

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