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access icon free Performance evaluation of IEC 61850 GOOSE-based inter-substation communication for accelerated distance protection scheme

Distance protection is the most widely used protection technique for transmission line protection due to its enhanced selectivity towards fault, fast response, and availability of various relay programming algorithms. However, when faults are detected in zone 2 of a relay, instantaneous tripping is not possible and are cleared after an inherent time delay. Sometimes, this increased disturbance duration may lead to system instability, power quality problems, or may result in increased plant damage. To address this issue, communication-assisted accelerated distance protection has been employed. To have this communication for tele-protection through standardised and interoperable means, an IEC 61850 GOOSE-based communication-assisted distance protection scheme is employed. This IEC 61850 GOOSE-based accelerated scheme must meet the stringent performance requirements. Thus, this study presents the experimental validation and performance evaluation of IEC 61850 GOOSE-based accelerated protection scheme by transporting GOOOSE messages through tunnelling in inter-substation for accelerated distance protection scheme. A system-in-the-loop platform has been developed to analyse the end-to-end delay performances of GOOSE messages under different WAN scenarios here. It has been found that for worst-case scenario, there is a significant operating time saving in the proposed scheme.

References

    1. 1)
      • 22. Ali, I., Hussain, S.M.S., Tak, A., et al: ‘Communication modeling for differential protection in IEC-61850-based substations’, IEEE Trans. Ind. Appl., 2018, 54, (1), pp. 135142.
    2. 2)
      • 15. Kumar, S., Das, N., Islam, S.: ‘Performance evaluation of a process bus architecture in a zone substation based on IEC 61850-9-2’. 2015 Asia-Pacific Power and Energy Engineering Conf. (APPEEC), Brisbane, pp. 15.
    3. 3)
      • 20. Ali, I., Hussain, S.M.S.: ‘Communication design for energy management automation in microgrid’, IEEE Trans. Smart Grid, 2018, 9, (3), pp. 20552064.
    4. 4)
      • 17. Sidhu, T.S., Yin, Y.: ‘Modelling and simulation for performance evaluation of IEC61850-based substation communication systems’, IEEE Trans. Power Deliv., 2007, 22, (3), pp. 14821489.
    5. 5)
      • 10. Schweitzer, E.O., Kasztenny, B., Guzmàn, A., et al: ‘Speed of line protection – can we break free of phasor limitations?’. 68th Annual Conf. for Protective Relay Engineers, 2015, pp. 448461.
    6. 6)
      • 21. ‘Communication networks and systems for power utility automation, part 90-1: use of IEC 61850 for the communication between substations’, IEC 61850-90-1, 1.0 edn, 2010.
    7. 7)
      • 24. Alstom Grid: ‘New York protection & automation guide’ (2011).
    8. 8)
      • 6. Jin, X., Gokaraju, R., Wierckx, R., et al: ‘High speed digital distance relaying scheme using FPGA and IEC 61850’, IEEE Trans. Smart Grid, 2018, 9, (5), pp. 43834394.
    9. 9)
      • 1. Anderson, P.M.: ‘Part 1: Protective devices and controls’ in Anderson, P.M. (Ed.): ‘Power System Protection’, (Wiley-IEEE Press, Piscataway, NJ, USA, 1999), pp. 3193.
    10. 10)
      • 16. Kumar, S., Das, N., Islam, S.: ‘Performance analysis of substation automation systems architecture based on IEC 61850’. 2014 Australasian Universities Power Engineering Conf. (AUPEC), Perth, WA, 2014, pp. 16.
    11. 11)
      • 14. Cheng, X., Lee, W.J., Pan, X.: ‘Modernizing substation automation systems: adopting IEC standard 61850 for modeling and communication’, IEEE Ind. Appl. Mag., 2017, 23, (1), pp. 4249.
    12. 12)
      • 25. Horowitz, S.H., Phadke, A.G.: ‘Power system relaying’ (Research Studies Press Limited, Chichester, 2008, 3rd edn.).
    13. 13)
      • 8. Apostolov, A.P.: ‘IEC 61850 communications based transmission line protection’. 11th IET Int. Conf. on Developments in Power Systems Protection (DPSP 2012), Birmingham, UK, 2012, pp. 16.
    14. 14)
      • 19. Zhang, Y., Cai, Z., Li, X., et al: ‘Analytical modeling of traffic flow in the substation communication network’, IEEE Trans. Power Deliv., 2015, 30, (5), pp. 21192127.
    15. 15)
      • 26. Distance protection schemes’, in ‘Network protection & automation guide’ (Published by Alstom Grid, 2011), pp. 193200. Available at https://goo.gl/k8ke2P.
    16. 16)
      • 18. Thomas, M.S., Ali, I.: ‘Reliable, fast, and deterministic substation communication network architecture and its performance simulation’, IEEE Trans. Power Deliv., 2010, 25, (4), pp. 23642370.
    17. 17)
      • 11. Falahati, B., Darabi, Z., Vakilian, M.: ‘Implementing distance line protection schemes among IEC61850-enabled substations’. 2014 IEEE PES T&D Conf. and Exposition, Chicago, IL, USA, 2014, pp. 15.
    18. 18)
      • 5. Xu, Z.Y., Huang, S.F., Ran, L., et al: ‘A distance protection relay for a 1000-kV UHV transmission line’, IEEE Trans. Power Deliv., 2008, 23, (4), pp. 17951804.
    19. 19)
      • 28. ‘Communication networks and systems in substations – communication requirements for functions and device models’, IEC 61850-5, 1.0 edn, 2003.
    20. 20)
      • 13. Das, N., Aung, T.T., Islam, S.: ‘Process-to-bay level peer-to-peer network delay in IEC 61850 substation communication systems’. 2013 Australasian Universities Power Engineering Conf..
    21. 21)
      • 7. Network protection & automation guide’ (Alstom Grid, Saint-Ouen, France, 2011), available at http://rpa.energy.mn/wp-content/uploads/2016/07/network-protection-and-automation-guide-book.pdf.
    22. 22)
      • 4. Xu, G., Yu, W., Griffith, D., et al: ‘Toward integrating distributed energy resources and storage devices in smart grid’, IEEE Internet Things J., 2017, 4, (1), pp. 192204.
    23. 23)
      • 30. ‘GOOSE Sender and Receiver (trail version) – INFO TECH’. Available at https://goo.gl/8yLw9A.
    24. 24)
      • 12. ‘Communication networks and systems for power utility automation’, IEC 61850 2nd edn., 2013.
    25. 25)
      • 27. ‘Designing non-deterministic PAC systems to meet deterministic requirements’. Available at https://www.pacw.org/no-cache/issue/june_2015_issue/deterministic_system/designing_nondeterministic_pac_systems_to_meet_deterministic_requirements.html.
    26. 26)
      • 29. ‘Riverbed Modeler – (formerly OPNET Modeler)’. Available at http://goo.gl/72SgAM.
    27. 27)
      • 3. Blaabjerg, F., Yang, Y., Yang, D., et al: ‘Distributed power-generation systems and protection’, Proc. IEEE, 2017, 105, (7), pp. 13111331.
    28. 28)
      • 23. Ali, I., Suhail Hussain, S.M.: ‘Control and management of distribution system with integrated DERs via IEC 61850 based communication’, Eng. Sci. Technol. Int. J., 2017, 20, (3), pp. 956964.
    29. 29)
      • 2. Jia, K., Bi, T., Li, W., et al: ‘Ground fault distance protection for paralleled transmission lines’, IEEE Trans. Ind. Appl., 2015, 51, (6), pp. 52285236.
    30. 30)
      • 9. Arnold, T., Adewole, A.C., Tzoneva, R.: ‘Performance testing and assessment of multi-vendor protection schemes using proprietary protocols and the IEC 61850 standard’. 2015 Int. Conf. on the Industrial and Commercial Use of Energy (ICUE), Cape Town, 2015, pp. 284290.
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