A quick method for electrical energy system load shedding based on equivalent areas
Subject Areas :
Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering
Shahrokh Shojaeian
1
,
Hamed Soltani
2
1 - Islamic Azad University
2 - Islamic Azad University
Received: 2022-03-06
Accepted : 2022-11-01
Published : 2022-09-01
Keywords:
Coherency Load Shedding,
UVLS,
Frequency Stability,
Power energy system,
Abstract :
The main purpose of the paper is to present a fast load shedding scheme, based on the concept of equivalent areas in large power systems. Performing load shedding on such systems with several generators in each area by using the conventional method is consuming a large amount of time. The proposed method can significantly reduce energy not supplied and is absolutely affordable for not only energy producers, but also energy consumers. At first, the coherent generators in the network will be detected based on a generation acceleration technique. The coherent generators will be identified without performing transient stability studies or the comparison of rotor swing angles, and only will be detected by using Jacobian matrix elements of the linearized power system model. Each group of the coherent generators will be replaced by an equivalent generator to introduce a new reduced model. All analytical calculation and decision variable factors will be achieved centrally with mentioned model and the only signal sends to the network, is a load shedding command. UVLS technique will be applied to the load shedding scheme. In this method, the priority is to shed the busloads with the most amplitude of the voltage drop after disturbance, so the network voltage and frequency stability will be maintained. The scale of load shedding level is proportional to online mismatch power between generation and demand. Finally, a simulation of the standard 39-buses IEEE network will be carried out to prove the strategy’s effectiveness.
References:
[1] Machowski, J. (1985). Dynamic equivalents for transient stability studies of electrical power systems. International journal of electrical power & energy systems, 7(4), 215-224.
[2] Ghafurian, A. (1983). Application of coherency and reduced order models to transient stability studies. International Journal of Electrical Power & Energy Systems, 5(3), 145-148.
[3] Kulkarni, A. V., Gao, W., & Ning, J. (2010, April). Study of power system load shedding scheme based on dynamic simulation. In IEEE PES T&D 2010(pp. 1-7). IEEE.
[4] Mahari, A., & Seyedi, H. (2016). A wide area synchrophasor-based load shedding scheme to prevent voltage collapse. International Journal of Electrical Power & Energy Systems, 78, 248-257.
[5] Li, Y., & Zhang, B. (2014, May). A new adaptive load shedding control strategy based on the transient voltage disturbance scale detection in power systems. In 2014 14th International Conference on Environment and Electrical Engineering(pp. 408-413). IEEE.
[6] Akrami, H., Shojaeian, S., & Lotfi, M. (2013). Presenting a New Algorithm for Determining Optimal Replaceable Capacity of Conventional Power Plants by Renewable Power Plants Based on Monte Carlo Method. Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering, 6(3), 47-54.
[7] Padiyar, K. R. (1996). Power system dynamics: stability and control. New York: John Wiley.
[8] Sankaranarayanan, V., Venugopal, M., Elangovan, S., & Rao, N. D. (1983). Coherency identification and equivalents for transient stability studies. Electric Power Systems Research, 6(1), 51-60.
[9] Znidi, F., Davarikia, H., & Rathore, H. (2021). Power Systems Transient Stability Indices: Hierarchical Clustering Based Detection of Coherent Groups Of Generators. arXiv preprint arXiv:2102.13286.
Khalkho, A. M., & Mohanta, D. K. (2021). Wide area power system transient stability prediction incorporating dynamic capability curve and generator bus coherency. Electrical Engineering, 103(3), 1445-1459.
Adom-Bamfi, G., & Frimpong, E. A. (2021). A Robust Scheme for Coherency Detection in Power Systems. JURNAL NASIONAL TEKNIK ELEKTRO.
Muthugala, V., Wadduwage, D. P., Wijayapala, A., & Fernando, R. (2021). Identification of coherent groups of generators for out-of-step protection using online measurements. Journal of the National Science Foundation of Sri Lanka, 49(1).
Jin, C., Li, W., Liu, L., Li, P., & Wu, X. (2019). A coherency identification method of active frequency response control based on support vector clustering for bulk power system. Energies, 12(16), 3155.
Gianfranco, C. (2021). Review of Clustering Methods for Slow Coherency-Based Generator Grouping. Energy Systems Research, 4(2 (14)), 5-20.
Ghafurian, A., & Berg, G. J. (1982, July). Coherency-based multimachine stability study. In IEE Proceedings C (Generation, Transmission and Distribution)(Vol. 129, No. 4, pp. 153-160). IET Digital Library.