Inertia Response of Power System Frequency Dynamics Based on The Quadratic Eigenvalue Approach

2022 Asia Power and Electrical Technology Conference (APET) Pub Date : 2022-11-11 DOI:10.1109/APET56294.2022.10073074

Zhenyao Li, Xueyi Wang, D. Gan

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Abstract

With the high penetration of renewable energy into the power system and the development and application of power electronic devices, the operation scale of the power system is increasing. Meanwhile, the frequency dynamic behavior of the power system is becoming more complex, which urgently needs effective frequency stability analysis methods and control means. To overcome the computational errors in the traditional system frequency response model, we established a frequency response model based on the full-state model of the power system. First, through the analytical solution of the time domain response of the state variables, we obtain the quantitative relationship between the system frequency-related characteristic quantities and the system parameters. Then, we transform the frequency stability problem into the quadratic eigenvalue problem and demonstrate that the reduction of system inertia increases the imaginary part of eigenvalues, which reduces the disturbance rejection capability of the system frequency inertia response. Finally, the correctness and validity of the above conclusions and methods are verified in the 10-machine 39-node system.

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基于二次特征值法的电力系统频率动力学惯性响应

随着可再生能源在电力系统中的高度渗透以及电力电子器件的发展和应用，电力系统的运行规模越来越大。同时，电力系统的频率动态特性也越来越复杂，迫切需要有效的频率稳定分析方法和控制手段。为克服传统系统频响模型的计算误差，建立了基于全状态模型的电力系统频响模型。首先，通过状态变量时域响应的解析解，得到系统频率相关特征量与系统参数之间的定量关系。然后，我们将频率稳定性问题转化为二次特征值问题，并证明了系统惯量的减小会增加特征值的虚部，从而降低系统频率惯量响应的抗扰能力。最后，在10机39节点系统中验证了上述结论和方法的正确性和有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 Asia Power and Electrical Technology Conference (APET)

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