Journal of Applied Science and Engineering

Published by Tamkang University Press

1.30

Impact Factor

1.60

CiteScore

Electrical Engineering

Junni Su1, Fengchao Chen1, Xin Zhang1, Lide Zhou1, Yipeng He1, Hua Zheng2This email address is being protected from spambots. You need JavaScript enabled to view it. 

1Dongguan Power Supply Bureau of Guangdong Power Grid Co., Ltd

2School of Electrical and Electronic Engineering, North China Electric Power University, Beijing 102208, China

 

Received: November 29, 2022
Accepted: April 15, 2023
Publication Date: September 4, 2023

 Copyright The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are cited.


Download Citation: ||https://doi.org/10.6180/jase.202403_27(3).0013  


Microgrid and distributed generation are more and more widely used in power systems. In this background, a control strategy based on consistency is proposed in this paper, to improve the optimal regulation ability of the AC/DC hybrid microgrid groups. The control strategy is divided into two levels: control strategy within a subnet and control between microgrid groups. At the level of subnet control, the power mapping factor and secondary adjustment term are introduced into the traditional droop control, to realize the autonomous and stable optimization in the island mode of a single sub microgrid. At the level of inter microgrid groups control strategy, the local control strategy of interlinking converter based on average power mapping factor is constructed, and the compensation term based on consistency is introduced to realize the power optimization operation between different microgrids jointly. Finally, the simulation model is established by Matlab/Simulink to prove the effectiveness of the method.


Keywords: AC/DC hybrid microgrid groups, Power mapping factor, Distributed control, Optimized control


  1. [1] G. Weiss, Q.-C. Zhong, T. C. Green, and J. Liang, (2004) “H/sup/spl infin//repetitive control of DC-AC converters in microgrids" IEEE Transactions on Power Electronics 19(1): 219–230. DOI: 10.1109/TPEL.2003.820561.
  2. [2] J. P. Lopes, C. L. Moreira, and A. Madureira, (2006) “Defining control strategies for microgrids islanded operation" IEEE Transactions on power systems 21(2): 916–924. DOI: 10.1109/TPWRS.2006.873018.
  3. [3] S. Zuo, A. Davoudi, Y. Song, and F. L. Lewis, (2016) “Distributed finite-time voltage and frequency restoration in islanded AC microgrids" IEEE Transactions on Industrial Electronics 63(10): 5988–5997. DOI: 10.1109/TIE.2016.2577542.
  4. [4] Q. Cao and W. Xie, (2020) “Optimal Frequency Control for Inverter-Based Micro-Grids Using Distributed FiniteTime Consensus Algorithms" IEEE Access 8: 185243–185252. DOI: 10.1109/ACCESS.2020.3030026.
  5. [5] A. Bidram and A. Davoudi, (2012) “Hierarchical structure of microgrids control system" IEEE Transactions on Smart Grid 3(4): 1963–1976. DOI: 10.1109/TSG.2012.2197425.
  6. [6] J. M. Guerrero, J. C. Vasquez, J. Matas, L. G. De Vicuña, and M. Castilla, (2010) “Hierarchical control of droop-controlled AC and DC microgrids—A general approach toward standardization" IEEE Transactions on industrial electronics 58(1): 158–172. DOI: 10.1109/TIE.2010.2066534.
  7. [7] J. W. Simpson-Porco, F. Dörfler, and F. Bullo, (2013) “Synchronization and power sharing for droop-controlled inverters in islanded microgrids" Automatica 49(9): 2603–2611.
  8. [8] Y. Xu and H. Sun, (2017) “Distributed finite-time convergence control of an islanded low-voltage AC microgrid" IEEE Transactions on Power Systems 33(3): 2339–2348. DOI: doi={10.1109/TPWRS.2017.2743011}.
  9. [9] M. Shi, X. Chen, J. Zhou, Y. Chen, J. Wen, and H. He, (2019) “PI-consensus based distributed control of AC microgrids" IEEE Transactions on Power Systems 35(3): 2268–2278. DOI: 10.1109/TPWRS.2019.2950629.
  10. [10] A. Shyam, S. Anand, and S. R. Sahoo, (2020) “Effect of communication delay on consensus-based secondary controllers in DC microgrid" IEEE Transactions on Industrial Electronics 68(4): 3202–3212. DOI: 10.1109/TIE.2020.2978719.
  11. [11] Z. Wang, W. Wu, and B. Zhang, (2015) “A fully distributed power dispatch method for fast frequency recovery and minimal generation cost in autonomous microgrids" IEEE Transactions on Smart Grid 7(1): 19–31. DOI: 10.1109/TSG.2015.2493638.
  12. [12] M. A. Shahab, B. Mozafari, S. Soleymani, N. M. Dehkordi, H. M. Shourkaei, and J. M. Guerrero, (2019) “Stochastic Consensus-Based Control of muGs With Communication Delays and Noises" IEEE Transactions on Power Systems 34(5): 3573–3581. DOI: 10.1109/TPWRS.2019.2905433.
  13. [13] Q. Li, D. W. Gao, H. Zhang, Z. Wu, and F.-Y. Wang, (2017) “Consensus-based distributed economic dispatch control method in power systems" IEEE transactions on smart grid 10(1): 941–954. DOI: 10.1109/TSG.2017.2756041.
  14. [14] X. Shen, H. Wang, D. Zhang, J. Li, R. Wang, and Q. Su, (2020) “Distributed finite-time secondary voltage restoration of droop-controlled islanded microgrids" IEEE Access 8: 118183–118191. DOI: 10.1109/ACCESS.2020.3004340.
  15. [15] M. A. Shahab, B. Mozafari, S. Soleymani, N. M. Dehkordi, H. M. Shourkaei, and J. M. Guerrero, (2019) “Distributed consensus-based fault tolerant control of islanded microgrids" IEEE Transactions on Smart Grid 11(1): 37–47. DOI: 10.1109/TSG.2019.2916727.
  16. [16] H. Yu, S. Niu, Z. Shao, and L. Jian, (2022) “A scalable and reconfigurable hybrid AC/DC microgrid clustering architecture with decentralized control for coordinated operation" International Journal of Electrical Power & Energy Systems 135: 107476.
  17. [17] Y. Zheng, S. Niu, Y. Shang, Z. Shao, and L. Jian, (2019) “Integrating plug-in electric vehicles into power grids: A comprehensive review on power interaction mode, scheduling methodology and mathematical foundation" Renewable and Sustainable Energy Reviews 112: 424–439.
  18. [18] H. Yu, S. Niu, Y. Zhang, and L. Jian, (2020) “An integrated and reconfigurable hybrid AC/DC microgrid architecture with autonomous power flow control for nearly/net zero energy buildings" Applied Energy 263: 114610.
  19. [19] Y. Zheng, Z. Shao, and L. Jian, (2021) “The peak load shaving assessment of developing a user-oriented vehicleto-grid scheme with multiple operation modes: The case study of Shenzhen, China" Sustainable Cities and Society 67: 102744.
  20. [20] F. Dörfler, J. W. Simpson-Porco, and F. Bullo, (2015) “Breaking the hierarchy: Distributed control and economic optimality in microgrids" IEEE Transactions on Control of Network Systems 3(3): 241–253.
  21. [21] H.-J. Yoo, T.-T. Nguyen, and H.-M. Kim, (2019) “Consensus-based distributed coordination control of hybrid AC/DC microgrids" IEEE Transactions on Sustainable Energy 11(2): 629–639.
  22. [22] P. Lin, C. Jin, J. Xiao, X. Li, D. Shi, Y. Tang, and P. Wang, (2018) “A distributed control architecture for global system economic operation in autonomous hybrid AC/DC microgrids" IEEE Transactions on Smart Grid 10(3): 2603–2617. DOI: 10.1109/TSG.2018.2805839.
  23. [23] J. Zhou, H. Zhang, Q. Sun, D. Ma, and B. Huang, (2017) “Event-based distributed active power sharing control for interconnected AC and DC microgrids" IEEE Transactions on Smart Grid 9(6): 6815–6828. DOI: doi={10.1109/TSG.2017.2724062}.
  24. [24] J. Yang, J. Hou, Y. Liu, and H. Zhang, (2021) “Distributed cooperative control method and application in power system" Trans. China Electrotech. Soc 36: 4035–4049.

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