首页|期刊导航|电工技术学报|面向新能源场站的构网型静止无功发生器阻抗建模及稳定性分析

面向新能源场站的构网型静止无功发生器阻抗建模及稳定性分析OA

Impedance Modeling and Stability Analysis of Grid-Forming Static Var Generator for Renewable Energy Power Plants

中文摘要英文摘要

近年来,构网控制技术在新能源领域得到了广泛应用,其中构网型静止无功发生器(SVG)被视为同步调相机的理想替代装备.然而,构网型SVG对新能源并网系统稳定性的具体影响机制尚未得到充分研究.该文聚焦构网型SVG在风电场中的应用及其对系统稳定性的影响,开展深入研究.首先,采用多谐波线性化建模方法,建立SVG跟网和构网控制模式下的阻抗模型,重点分析 SVG 输出阻抗的负阻尼分布特征,并对两种模式下的阻抗特性进行详细的量化分析对比.然后,构建包含SVG的风电场阻抗网络模型,系统地探讨不同模式SVG对风电场稳定性的影响规律.研究结果表明:与跟网型SVG相比,构网型SVG的负阻尼阻抗特征得以显著改善,构网型 SVG具备与同步调相机相当的弱电网稳定运行能力.最后,通过 RT-Lab硬件在环实验平台,以哈密地区某风电场为例进行多工况实验,实验结果验证了该文分析结果的正确性.

To enhance grid-connected system voltage support and oscillation suppression capability,new energy power plants are equipped with static var generator(SVG)as a reactive power compensation device.Under the background of widespread deployment of reactive power compensation devices in new energy power stations,grid-forming(GFM)SVG demonstrate superior grid adaptability compared to traditional grid-following(GFL)SVG and synchronous condenser(SC),owing to their self-synchronizing characteristics,second-level dynamic response,and transient support capability.However,current research on the impact of GFM SVG on the stability of new energy power plants is still at an exploratory stage.In particular,the impedance modeling of GFM SVG and the analysis of its influence mechanisms on the stability of new energy power plants still require further in-depth studies.To address the aforementioned issues,this paper establishes the impedance characteristic model of GFM SVG and constructs the aggregated impedance of wind farms after GFM SVG integration.It compares the frequency characteristics between grid-forming and grid-following SVGs,and conducts a quantitative analysis of the influence mechanisms of GFM SVG's key control parameters on the stability of new energy power plants. First,a multi-harmonic linearization modeling approach is adopted to derive harmonic small-signal mathematical expressions introduced by the power circuit and control loops of GFM SVG.Based on this,the sequence impedance model of GFM SVG is established.Furthermore,a detailed comparative analysis of impedance characteristics between GFM SVG and GFL SVG is conducted.The analytical results demonstrate that the grid-forming control significantly enhances the amplitude of SVG impedance characteristics in both low-frequency and high-frequency ranges.Additionally,grid-forming control improves the negative damping characteristics in sub/super-synchronous frequency bands of impedance,thereby reducing the risk of grid-connected oscillation. To quantitatively evaluate the impact of GFM SVG on wind farm stability,this study employs an impedance aggregation method to establish an aggregated impedance model of a wind farm with transmission lines and transformers after GFM SVG integration,using a wind farm in the Hami region as a case study.A comparative analysis is conducted on the aggregated impedance models of wind farms integrated with GFM SVG,GFL SVG,and SCs under three different grid connection scenarios,the stability analysis results demonstrate that:The integration of GFM SVG into wind farms can effectively narrow the negative damping region of the aggregated wind farm impedance while avoiding the introduction of additional impedance crossover points,thereby enhancing the grid-connected stability of new energy power plants.Building on this foundation,the study conducts an in-depth analysis of the impact mechanisms of grid-forming SVG's key control parameters(including the DC voltage frequency modulation coefficient,reactive voltage inertia coefficient,and virtual impedance)on the aggregated impedance of SVG-integrated wind farms and their grid-connected stability.Furthermore,the stability boundaries for the DC voltage frequency modulation coefficient and reactive voltage inertia coefficient in wind farm grid-connected systems are established quantitatively,proposing systematic parameter optimization methodologies.Finally,the impact of transmission line parameters on grid-connected system stability is analyzed.Short-circuit ratio improvement percentage(α)is defined to quantify the improvement in the adaptability of the weak grid after integrating different reactive power compensation devices into new energy power plants.Compared to GFL SVG,wind farms integrated with GFM SVG exhibit significantly enhanced weak grid adaptability and damping effects comparable to synchronous condensers.

赵力轩;陈新;张东辉

江苏省新能源发电与电能变换重点实验室(南京航空航天大学自动化学院) 南京 211106江苏省新能源发电与电能变换重点实验室(南京航空航天大学自动化学院) 南京 211106江苏省新能源发电与电能变换重点实验室(南京航空航天大学自动化学院) 南京 211106

信息技术与安全科学

静止无功发生器(SVG)同步调相机构网控制阻抗模型稳定性分析风电场

Static var generator(SVG)synchronous compensatorgrid-forming(GFM)controlimpedance modelstability analysiswind farm

《电工技术学报》 2026 (3)

849-864,16

国家自然科学基金面上项目资助(52277186).

10.19595/j.cnki.1000-6753.tces.242392

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