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Gorjian, Mehrdad, Ghanbarian, Mohammad Mehdi, Fatehi Dinarlo, Mohammad Hossein, Taghizadeh, Mehdi. (1400). Dynamic modeling and microgrid frequency control connecting to the power grid in different modes. نشریه هنرهای کاربردی, 13(1), 3113-3129. doi: 10.22075/ijnaa.2021.25343.2989
Mehrdad Gorjian; Mohammad Mehdi Ghanbarian; Mohammad Hossein Fatehi Dinarlo; Mehdi Taghizadeh. "Dynamic modeling and microgrid frequency control connecting to the power grid in different modes". نشریه هنرهای کاربردی, 13, 1, 1400, 3113-3129. doi: 10.22075/ijnaa.2021.25343.2989
Gorjian, Mehrdad, Ghanbarian, Mohammad Mehdi, Fatehi Dinarlo, Mohammad Hossein, Taghizadeh, Mehdi. (1400). 'Dynamic modeling and microgrid frequency control connecting to the power grid in different modes', نشریه هنرهای کاربردی, 13(1), pp. 3113-3129. doi: 10.22075/ijnaa.2021.25343.2989
Gorjian, Mehrdad, Ghanbarian, Mohammad Mehdi, Fatehi Dinarlo, Mohammad Hossein, Taghizadeh, Mehdi. Dynamic modeling and microgrid frequency control connecting to the power grid in different modes. نشریه هنرهای کاربردی, 1400; 13(1): 3113-3129. doi: 10.22075/ijnaa.2021.25343.2989

Dynamic modeling and microgrid frequency control connecting to the power grid in different modes

International Journal of Nonlinear Analysis and Applications
مقاله 252، دوره 13، شماره 1، خرداد 2022، صفحه 3113-3129    اصل مقاله (1.91 M)
نوع مقاله: Research Paper
شناسه دیجیتال (DOI): 10.22075/ijnaa.2021.25343.2989
نویسندگان
Mehrdad Gorjian؛ Mohammad Mehdi Ghanbarian* ؛ Mohammad Hossein Fatehi Dinarlo؛ Mehdi Taghizadeh
Department of Electrical Engineering, Kazerun Branch, Islamic Azad University, Kazerun, Iran
تاریخ دریافت: 15 مهر 1400،  تاریخ بازنگری: 03 آذر 1400،  تاریخ پذیرش: 26 آذر 1400 
چکیده
In this paper, using the potential of microgrid surface batteries, the frequency support of the power system in different operating modes was discussed. The study suggested that the process could be supported by a set of batteries in the microgrid (in the mains-connected mode and in the island mode, with the decentralized participation of each, in frequency support (power system or microgrid) in Different operating modes, were addressed. The approach used in this paper was to use a convex optimization algorithm. In this way, the batteries independently measured the system frequency and considering their charging mode injected the optimal power into the system, and A convex optimization algorithm will prove that the local optimal point (scattered battery injection) is the optimal point. It will also be universal (optimal system frequency control). Studies in system simulation in two modes of microgrid connected to the main grid and island microgrid have yielded several points.
کلیدواژه‌ها
Dynamic modeling؛ microgrid؛ frequency control؛ power grid
مراجع

[1] M.R. Aghamohammadi and H. Abdolahinia, A new approach for optimal sizing of battery energy storage system for primary frequency control of islanded microgrid, Int. J. Electron. Power Energy Syst. 54 (2014) 333–325.

[2] H. Bevrani, F. Habibi, P. Babahajyani, M. Watanabe and Y. Mitani, Intelligent frequency control in an ac microgrid: online PSO-based fuzzy tuning approach, IEEE Trans. Smart Grid 3 (2012) 1944–1935.

[3] A.M. Bouzid, J.M. Guerrero, A. Cheriti, M. Bouhamida, P. Sicard and M. Benghanem, A survey on control of electric power distributed generation systems for microgrid applications, Renew. Sustain. Energy Rev. 44 (2015) 166–151.

[4] S. Boyd and L. Vandenberghe, Convex Optimization, Cambridge University Press, 2004.

[5] Y. Han, P.M. Young, A. Jain and D. Zimmerle, Robust control for microgrid frequency deviation reduction with attached storage system, IEEE Trans. Smart Grid 6 (2015) 565–551.

[6] F. Katiraei, M. Iravani and P.W. Lehn, Micro-grid autonomous operation during and subsequent to islanding process, IEEE Trans. Power Delivery 20 (2005) 251–248.

[7] J.-Y. Kim, J.-H. Jeon, S.-K. Kim, C. Cho, J.H. Park, H.-M. Kim and K.-Y. Nam, Cooperative control strategy of energy storage system and microsources for stabilizing the microgrid during islanded operation, IEEE Trans. Power Electron. 25 (2010) 3048–3031.

[8] X. Lu, J. M. Guerrero, K. Sun, J.C. Vasquez, R. Teodorescu and L. Huang, Hierarchical control of parallel AC-DC converter interfaces for hybrid microgrids, IEEE Trans. Smart Grid 5 (2014) 692–683.

[9] V. Moghadam, R. Mohammad, R.T. Ma and R. Zhang, Distributed frequency control in smart grids via randomized demand response, IEEE Trans. Smart Grid 5 (2014) 2809–2198.

[10] J. Pahasa and I. Ngamroo, PHEVs bidirectional charging/discharging and SoC control for microgrid frequency stabilization using multiple MPC, IEEE Trans. Smart Grid 6 (2015) 533–526.

[11] I. Serban and C. Marinescu, Battery energy storage system for frequency support in microgrids and with enhanced control features for uninterruptible supply of local loads, Int. J. Electr. Power Energy Syst. 54 (2014) 441–432.

[12] A. Teninge, C. Jecu, D. Roye, S. Bacha, J. Duval and R. Belhomme, Contribution to frequency control through wind turbine inertial energy storage, IET Renew. Power Gen. 3 (2009) 310–358.

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