典型独立同步电网新能源高渗透率运行中的频率稳定挑战与应对措施(上)

莫维科<sup>1</sup>; 雷剑雄<sup>1</sup>; 陈亦平<sup>2</sup>; 陈皓勇<sup>3</sup>; 和敬涵<sup>1</sup>

引用本文:	莫维科,雷剑雄,陈亦平,等.典型独立同步电网新能源高渗透率运行中的频率稳定挑战与应对措施(上)[J].电力系统保护与控制,2025,53(16):177-187.[点击复制]
	MO Weike,LEI Jianxiong,CHEN Yiping,et al.Frequency stability challenges and countermeasures in typical isolated synchronous power grids with high penetration of renewable energy (part I)[J].Power System Protection and Control,2025,53(16):177-187[点击复制]

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典型独立同步电网新能源高渗透率运行中的频率稳定挑战与应对措施(上)
莫维科¹,雷剑雄¹,陈亦平²,陈皓勇³,和敬涵¹
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(1.暨南大学国际能源学院/能源电力研究中心，广东珠海 519070;2.南方电网新型电力系统(北京) 研究院有限公司，北京 102218;3.华南理工大学电力学院，广东广州 510640)

摘要:

在高比例新能源与电力电子设备广泛应用的背景下，基于国际独立同步电网案例，分析了新能源高渗透率运行下面临的频率稳定挑战。首先，选取爱尔兰岛、得州和澳大利亚电网，梳理其系统特征与新能源发展路径，分析在新能源高渗透率运行下的频率稳定风险。然后，从系统惯量降低、调频资源稀缺、频率调节手段多样化、频率振荡风险加剧及分布式新能源对低频减载的影响5个维度，总结各电网在高比例新能源接入背景下面临的共性挑战。最后，总结高比例新能源接入下频率稳定问题的系统性特征，提出临界惯量评估、多源调频协同、频率振荡抑制与减载策略优化等研究方向，为构建新型电力系统提供理论基础和现实参考。

关键词: 独立同步电网爱尔兰岛电网得州电网澳大利亚电网新能源高渗透率频率稳定

DOI：10.19783/j.cnki.pspc.240486

投稿时间：2024-04-21修订日期：2025-05-15

基金项目:国家重点研发计划项目资助(2022YFB2403500)

Frequency stability challenges and countermeasures in typical isolated synchronous power grids with high penetration of renewable energy (part I)

MO Weike¹,LEI Jianxiong¹,CHEN Yiping²,CHEN Haoyong³,HE Jinghan¹

(1. International Energy College/Energy and Electricity Research Center, Jinan University, Zhuhai 519070, China; 2. Southern Power Grid New Energy System (Beijing) Research Institute Co., Ltd., Beijing 102218, China; 3. School of Electric Power, South China University of Technology, Guangzhou 510640, China)

Abstract:

In the context of the widespread integration of high-proportion renewable energy and power electronic devices, this paper analyzes the challenges faced by isolated synchronous power grids operating with high renewable penetration. First, the Irish, Texas, and Australian power grids are selected to review their system characteristics and renewable development paths, identifying frequency stability risks associated with high-penetration operation. Then, from five key perspectives: reduced system inertia, scarcity of frequency regulation resources, diversification of frequency regulation methods, increased risk of frequency oscillations, and the impact of distributed renewables on under-frequency load shedding, the common challenges faced by these grids are summarized. Finally, the systemic characteristics of frequency stability issues under high renewable penetration are identified, and future research directions are proposed, including critical inertia assessment, coordinated multi-source frequency regulation, oscillation suppression, and optimization of load shedding strategies. These insights aim to provide both a theoretical foundation and practical reference for building new power systems.

Key words: isolated synchronous power grid Eirgrid and SONI ERCOT AEMO high penetration of renewable energy frequency stability

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