Presenting a New Model of The Comprehensive Power Controller in The Power System
Keywords:
Comprehensive Power Controller, Load Distribution, Reactive Power Control, Active Power ControlAbstract
This article presents a detailed analysis and proposal for a comprehensive power controller in power systems. The controller focuses on controlling line parameters and power currents in transmission lines, aiming to maximize energy transmission capacity, enhance network reliability, and reduce line losses. By effectively managing energy consumption and optimizing power system efficiency, the proposed controller offers significant benefits. The model introduces a novel approach based on simple circuit elements like resistance and reactance, without requiring any changes to the network's Jacobian matrix dimensions. The relationships of this new model are derived and applied to the Duchesne power system, serving as a demonstration of its effectiveness. Furthermore, extensive simulations are conducted on fourteen standard tire systems to validate the efficiency and performance of the proposed model. Through this research, the potential for improved power system control and optimization is explored, contributing to the overall advancement of energy transmission and management.
References
E. Acha, C. R. Fuerte-Esquivel, H. Ambriz-Perez, and C. Angeles-Camacho, FACTS: modelling and simulation in power networks. John Wiley & Sons, 2004.
E. Barrios-Martínez and C. Ángeles-Camacho, "Technical comparison of FACTS controllers in parallel connection," Journal of applied research and technology, vol. 15, no. 1, pp. 36-44, 2017.
I. S. Bayram and S. Bayhan, "Location analysis of electric vehicle charging stations for maximum capacity and coverage," in 2020 IEEE 14th international conference on compatibility, power electronics and power engineering (CPE-POWERENG), 2020, vol. 1: IEEE, pp. 409-414.
J. Beerten, S. Cole, and R. Belmans, "A sequential AC/DC power flow algorithm for networks containing multi-terminal VSC HVDC systems," in IEEE PES general meeting, 2010: IEEE, pp. 1-7.
G. S. Chawda, A. G. Shaik, O. P. Mahela, S. Padmanaban, and J. B. Holm-Nielsen, "Comprehensive review of distributed FACTS control algorithms for power quality enhancement in utility grid with renewable energy penetration," IEEE Access, vol. 8, pp. 107614-107634, 2020.
Z. Ding, F. Teng, P. Sarikprueck, and Z. Hu, "Technical review on advanced approaches for electric vehicle charging demand management, part ii: Applications in transportation system coordination and infrastructure planning," IEEE Transactions on Industry Applications, vol. 56, no. 5, pp. 5695-5703, 2020.
S. Frank, I. Steponavice, and S. Rebennack, "Optimal power flow: A bibliographic survey I: Formulations and deterministic methods," Energy systems, vol. 3, pp. 221-258, 2012.
A. Gabash and P. Li, "Active-reactive optimal power flow in distribution networks with embedded generation and battery storage," IEEE Transactions on Power Systems, vol. 27, no. 4, pp. 2026-2035, 2012.
P. Gaderi Baban, Y. Naderi, G. Ranjbaran, and S. Homayounmajd, "Control of delayed nonlinear model of type 1 diabetes using an improved sliding model strategy," Journal of Bioengineering Research, vol. 3, no. 3, pp. 8-15, 2021.
E. Ghahremani and I. Kamwa, "Optimal placement of multiple-type FACTS devices to maximize power system loadability using a generic graphical user interface," IEEE transactions on power systems, vol. 28, no. 2, pp. 764-778, 2012.
X.-P. Zhang, C. Rehtanz, and B. Pal, "Flexible AC transmission systems: modelling and control," Springer Science & Business Media, 2012.
N. G. Hingorani and L. Gyugyi, "Understanding FACTS: concepts and technology of flexible AC transmission systems," Wiley Online Library, 2000.
H. Song and A. Jhons, "Flexible AC Transmission Systems," United kingdom University.The Institution of Electrical Engineers, London, 599 p., 1999.
X.-P. Zhang, C. Rehtanz, and B. Pal, "Flexible AC transmission systems: modelling and control," Springer Science & Business Media, 2012.
K. M. Nor, H. Mokhlis, and T. A. Gani, "Reusability techniques in load-flow analysis computer program," IEEE Trans Power Syst, vol. 19, pp. 1754-1762, 2004.
M. Izadi, M. Jabari, N. Izadi, M. Jabari, and A. Ghaffari, "Adaptive Control based on the Lyapunov Reference Model Method of Humanoid Robot Arms using EFK," in 2021 13th Iranian Conference on Electrical Engineering and Computer Science (ICEESC), 2021.
S. Bhowmick, B. Das, and N. Kumar, "An indirect UPFC model to enhance reusability of Newton power flow codes," IEEE Trans Power Delivery, vol. 23, pp. 2079-2088, 2008.
S. Bhowmick, B. Das, and N. Kumar, "An advanced IPFC model to reuse Newton power flow codes," IEEE Trans Power Syst, vol. 24, pp. 525-532, 2009.
S. Bhowmick, B. Das, and N. Kumar, "An advanced static synchronous compensator model to reuse Newton and decoupled power flow codes," Electr Power Compon Syst, vol. 39, pp. 1647-1666, 2011.
S. Izadi, K. Jabari, M. Izadi, B. Khadem Hamedani, and A. Ghaffari, "Identification and Diagnosis of Dynamic and Static Misalignment in Induction Motor Using Unscented Kalman Filter," in 2021 13th Iranian Conference on Electrical Engineering and Computer Science (ICEESC), 2021.
S. Kamel, F. Jurado, and Z. Chen, "Power flow control for transmission networks with implicit modeling of static synchronous series compensator," Int J Electr Power Energy Syst, vol. 64, pp. 911-912, 2015.
S. Kamel and F. Jurado, "Power flow analysis with easy modelling of interline power flow controller," Electr Power Syst Res, vol. 108, pp. 234-244, 2014.
.
