Frequency Oscillation Analysis of Power System With Multiple Governor Deadbands

• Published in: IEEE access Vol. 8; pp. 88085 - 88092
• Main Authors: Fan, Chengwei, Chen, Gang, Chen, Zhen, Shi, Huabo, Liu, Chang, Teng, Yufei
• Format: Journal Article
• Language: English
• Published: Piscataway IEEE 2020; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Amplitudes; extended description function; Extremely low frequencies; Frequency analysis; Frequency stability; Governors; multiple governor deadbands; nonlinear composite system; Segments; Stability analysis; Systems stability; Turbines; Ultra-low frequency oscillation
• ISSN: 2169-3536; 2169-3536
• DOI: 10.1109/ACCESS.2020.2993061

In recent years, the ultra-low frequency oscillation of power system is one of the most concerned frequency stability problem. The governor deadband are considered as one of the main influences. However, the existing methods can only deal with single deadband segment. As for a multi-machine system with multiple deadband segments, it lacks the analysis method for frequency oscillation. To solve this problem, this paper first define the extended description function applied to nonlinear composite system according to the principle of traditional description function method. The extended description function can quantify the relationship of input and output of a system with multiple nonlinear segments. Then, based on the uniform frequency model of multiple governors, the turbines and governors of hydro and thermal power units with different deadband widths are equivalent to one extended description function. The locus of minus reciprocal of the extended description function with oscillation amplitude and the Nyquist curve of the generator are plotted on the complex plane for the analysis of system stability. Next, the critical oscillation amplitude of disturbance to trigger the system frequency oscillation is calculated according to the point of intersection of both curves. Finally, the simulation results show that the critical oscillation amplitude can reflect the stability of system. The change of deadband width is positively correlated with the critical oscillation amplitude. The appropriate setting of deadband and configuration of hydro-thermal generation are effective measures to suppress the ultra-low frequency oscillation while retain the ability of frequency regulation.