并网风力发电系统的频率响应分析与改进

IF 6.1 2区 工程技术 Q2 ENERGY & FUELS IEEE Transactions on Energy Conversion Pub Date : 2024-10-28 DOI:10.1109/TEC.2024.3487202
Lei Liu;Liansong Xiong;Xianjue Luo;Xiaohan Zhao;Yonghui Liu;Xiaokang Liu
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引用次数: 0

摘要

并网型风力发电系统能够对电网频率变化做出主动响应。然而,随着干扰强度的增加,GFM WGSs的频响性能逐渐不足,导致网格频率偏差容易超过相关阈值。由于GFM WGS的建筑频率特性及其与电网频率的相互作用,其FR机制尚不清楚,这对提高GFM WGS的FR性能提出了挑战。为此,本文分析了GFM WGSs的频响机理,提出了一种频响增强控制方法。首先,建立了反映上述频率相互作用的FR模型。然后,从物理角度分析了GFM WGS的增益机理,包括间接增益和直接增益,发现了两种相应的增益增强路径:1)GFM控制中基于工频环参数的间接增益路径,2)基于WGS功率的直接增益路径。在直接路径的基础上,提出了一种快速预置功率来校正扰动后wgs参考功率的增益控制方法。最后,通过实验验证了所提控制的极好FR增强效果。
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Frequency Response Analysis and Enhancement of Grid-Forming Wind Generation Systems
Grid-forming (GFM) wind generation systems (WGSs) can actively respond to the grid frequency change during disturbances. However, with increasing intensities of disturbances, the frequency response (FR) performance of GFM WGSs gradually becomes insufficient, resulting that grid frequency deviations are prone to exceeding pertinent thresholds. Due to the properties of GFM WGS building frequency and its interaction with the grid frequency, the FR mechanism is not yet clear, which poses a challenge to enhancing the FR performance of GFM WGSs. To this end, this paper analyzes the FR mechanism of GFM WGSs and proposes an FR enhancement control. Firstly, an FR model that can reflect the above frequency interaction is established. Then, the FR mechanism of GFM WGSs is analyzed from a physical perspective, including indirect and direct FR. Two corresponding FR enhancement paths are discovered: i) an indirect path based on adjusting the parameters of power-frequency loop in GFM control, and ii) a direct path based on adjusting the WGS power. Based on the direct path, a novel FR enhancement control is developed by promptly presetting power to correct the reference power of WGSs after disturbances. Finally, the superb FR enhancement effect of the proposed control is verified by experiments.
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来源期刊
IEEE Transactions on Energy Conversion
IEEE Transactions on Energy Conversion 工程技术-工程:电子与电气
CiteScore
11.10
自引率
10.20%
发文量
230
审稿时长
4.2 months
期刊介绍: The IEEE Transactions on Energy Conversion includes in its venue the research, development, design, application, construction, installation, operation, analysis and control of electric power generating and energy storage equipment (along with conventional, cogeneration, nuclear, distributed or renewable sources, central station and grid connection). The scope also includes electromechanical energy conversion, electric machinery, devices, systems and facilities for the safe, reliable, and economic generation and utilization of electrical energy for general industrial, commercial, public, and domestic consumption of electrical energy.
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