Optimal Design Method of Flexible Excitation System for Improving Power System Stability

2020 IEEE Industry Applications Society Annual Meeting Pub Date : 2020-10-10 DOI:10.1109/IAS44978.2020.9334907

Tiantian Zhang, Liping Cheng, Silin He, M. Yu, C. Mao, Dan Wang, Jiancheng Zhang, Bing Han, Zheng Tao

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引用次数: 3

Abstract

Providing sufficient damping over the full frequency range of the low frequency oscillation (LFO) is a challenge for the power system stabilizer (PSS). The flexible excitation system of the synchronous generator is a novel structure with full-controlled devices, which has two damping channels. One is controlled by PSS, and another can be controlled by the reactive power damping controller (RPDC) to improve the damping over the lower-frequency range. A novel structure, avoiding the limitation of the excessive higher-frequency gain on lower-frequency damping, is adopted in RPDC. The parameters design method of the flexible excitation system is proposed. A SMIB system is established in RTDS (real time digital system), and various oscillation frequencies (i.e. 1.2 Hz, 0.5 Hz, and 0.3 Hz) are obtained by adjusting TJ. The comparisons between the flexible and conventional excitation system show that the flexible excitation system can provide more damping to reduce the steady time, decrease the oscillation amplitude, and improve the power system stability over the full frequency range of LFO, especially over the lower-frequency range.

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提高电力系统稳定性的柔性励磁系统优化设计方法

在低频振荡(LFO)的整个频率范围内提供足够的阻尼是电力系统稳定器(PSS)面临的一个挑战。同步发电机柔性励磁系统是一种新型的全控制装置结构，具有两个阻尼通道。一个由PSS控制，另一个由无功阻尼控制器(RPDC)控制，以改善低频范围的阻尼。采用了一种新颖的结构，避免了高频增益过大对低频阻尼的限制。提出了柔性励磁系统的参数设计方法。在RTDS(实时数字系统)中建立SMIB系统，通过调整TJ得到1.2 Hz、0.5 Hz和0.3 Hz的振荡频率。柔性励磁系统与传统励磁系统的比较表明，柔性励磁系统可以提供更大的阻尼，缩短稳态时间，减小振荡幅值，提高电力系统在LFO全频率范围内，特别是低频范围内的稳定性。

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2020 IEEE Industry Applications Society Annual Meeting

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