Power Oscillation Damping Controllers for Grid-Forming Power Converters in Modern PowerSystems

arXiv - EE - Systems and Control Pub Date : 2024-09-16 DOI:arxiv-2409.10726

Elia Mateu-Barriendos, Onur Alican, Javier Renedo, Carlos Collados-Rodriguez, Macarena Martin, Edgar Nuño, Eduardo Prieto-Araujo, Oriol Gomis-Bellmunt

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Abstract

Inter-area oscillations have been extensively studied in conventional power systems dominated by synchronous machines, as well as methods to mitigate them. Several publications have addressed Power Oscillation Damping (POD) controllers in grid-following voltage source converters (GFOL). However, the performance of POD controllers for Grid-Forming voltage source converters (GFOR) in modern power systems with increased penetration of power electronics requires further investigation. This paper investigates the performance of GFORs and supplementary POD controllers in the damping of electromechanical oscillations in modern power systems. This paper proposes POD controllers in GFORs by supplementary modulation of active- and reactive-power injections of the converter and both simultaneously (POD- P, POD-Q and POD-PQ, respectively). The proposed POD controllers use the frequency imposed by the GFOR as the input signal, which has a simple implementation and it eliminates the need for additional measurements. Eigenvalue-sensitivity methods using a synthetic test system are applied to the design of POD controllers in GFORs, which is useful when limited information of the power system is available. This paper demonstrates the effectiveness of POD controllers in GFOR converters to damp electromechanical oscillations, by small-signal stability analysis and non-linear time-domain simulations in a small test system and in a large-scale power system.

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现代电力系统中并网型电力转换器的功率振荡阻尼控制器

在以同步电机为主导的传统电力系统中，人们已经广泛研究了区域间振荡以及缓解振荡的方法。然而，在电力电子技术渗透率不断提高的现代电力系统中，电网电压源变换器（GFOR）的功率振荡抑制（POD）控制器的性能还需要进一步研究。本文研究了现代电力系统中 GFOR 和辅助 POD 控制器在抑制机电振荡方面的性能。本文提出了 GFOR 中的 POD 控制器，即同时对变流器的有功功率注入和无功功率注入进行补充调制（分别为 POD-P、POD-Q 和 POD-PQ）。拟议的 POD 控制器使用 GFOR 施加的频率作为输入信号，实现简单，无需额外测量。使用合成测试系统的特征值灵敏度方法被应用于 GFOR 中 POD 控制器的设计，这在电力系统信息有限的情况下非常有用。本文通过在小型测试系统和大型电力系统中进行小信号稳定性分析和非线性时域仿真，证明了 POD 控制器在 GFOR 变流器中抑制机电振荡的有效性。

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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arXiv - EE - Systems and Control

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