基于调频特性补偿的电池储能系统暂态调频策略

doi:10.19595/j.cnki.1000-6753.tces.251548

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摘要作为新型电力系统的重要组成部分,电网侧分布式部署的电池储能系统（BESS）具有巨大的暂态调频潜力。现有研究多集中在利用BESS通过惯性或阻尼控制模拟同步机调频特性,难以充分发挥BESS能量对暂态频率响应的改善效果,限制了其主动支撑能力。为此,该文突破常规控制结构,提出一种适用于多BESS的新型暂态调频策略。首先,构建含BESS能量动力学的系统暂态频率响应模型。其次,提出针对其他电源调频特性延迟的补偿策略,旨在获得过阻尼暂态频率响应,并设计用于运行状态切换的参考功率生成环节。然后,理论分析所提策略的调频效果和BESS能量利用情况。最后,在不同扰动下通过包含3个BESS的IEEE 39节点修正系统验证了所提策略在改善暂态频率响应和优化BESS能量利用方面的优越性。

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	黄子洋
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关键词 ：电池储能系统, 暂态调频, 暂态频率响应, 调频特性补偿, 能量利用

Abstract：The inherent volatility and intermittency of renewable energy output exacerbate the mismatch between supply and demand. Simultaneously, the gradual replacement of synchronous generators by renewable energy weakens system inertia and damping, posing threats to the security and stability of system frequency across multiple timescales. Due to the delayed response of synchronous generators, there is an urgent need to explore new frequency regulation resources and strategies. Distributed battery energy storage systems (BESSs), offer advantages such as precise controllability, rapid response, and flexible adjustment, enabling them to support transient auxiliary services like frequency and voltage regulation. Conventional frequency regulation strategies for BESS are autonomous and highly reliable but fail to account for the impact on other power sources or the actual system requirements, making it difficult to fully leverage active support capabilities of BESS under various operating conditions. When BESS is used to improve the frequency regulation characteristics of other power sources, its integration is typically tailored to specific source types, resulting in model-dependent and highly customized strategies that lack universality.
To address these limitations, this paper proposes a novel transient frequency regulation strategy based on frequency regulation characteristic compensation. First, the energy dynamic model of the BESS is derived in the transient timescale, and the frequency regulation characteristics of multiple types of power sources are uniformly described using linearized frequency regulation transfer functions. A system transient frequency response model incorporating multiple BESSs is then established to accurately reflect the contribution of BESSs during transients. Subsequently, a universal compensation strategy for frequency regulation characteristic delays of power sources is proposed. Following this, with the objective of maximizing the utilization of BESS reserve energy, the power distribution coefficient and initial inertia coefficient required by the strategy are configured to enhance the active frequency support capability of BESS under different operating conditions. Finally, the effectiveness and superiority of the proposed strategy are verified via theoretical analysis and case studies of IEEE 39-bus system.
The main conclusion of this paper can be summarized as follows:
(1)Under different system conditions and various disturbances, the proposed strategy exhibits adaptability. Its frequency regulation performance and BESS energy utilization rate are significantly superior to conventional SIC and adaptive SIC strategies; it also outperforms constant frequency control strategy in terms of frequency regulation effect while ensuring the continuity of energy utilization.
(2)The proposed strategy can achieve an overdamped transient frequency response when the power disturbance is small. When the power disturbance is large, it fully releases the reserve energy of BESS for frequency regulation characteristic compensation, thereby maximizing the frequency extremes while meeting system frequency regulation requirements and ensuring BESS operational safety.
(3)As the proportion of renewable energy replacing synchronous generators increases, the BESS energy required for complete compensation of frequency regulation characteristic decreases, making it easier to achieve optimal transient frequency regulation using the proposed strategy.

Key words： Battery energy storage system transient frequency regulation transient frequency response frequency regulation characteristic compensation energy utilization

收稿日期: 2025-09-02

PACS:

TM732

基金资助:国家电网有限公司科技项目资助（5100-202499006A-1-1-ZN）

通讯作者: 李庚银男,1964年生,教授,博士生导师,研究方向为新能源电力系统分析与控制、新型输配电技术、电力经济等。E-mail：ligy@ncepu.edu.cn

作者简介: 黄子洋男,1995年生,博士研究生,研究方向为新能源电力系统频率调节、分布式控制等。E-mail：120192101053@ncepu.edu.cn

引用本文:

黄子洋, 张晓楠, 李庚银, 李菁竹, 田鑫. 基于调频特性补偿的电池储能系统暂态调频策略[J]. 电工技术学报, 2026, 41(9): 2949-2962. Huang Ziyang, Zhang Xiaonan, Li Gengyin, Li Jingzhu, Tian Xin. Transient Frequency Regulation Strategy for Battery Energy Storage System Based on Frequency Regulation Characteristic Compensation. Transactions of China Electrotechnical Society, 2026, 41(9): 2949-2962.

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[1] 付媛, 王毅, 张祥宇, 等. 变速风电机组的惯性与一次调频特性分析及综合控制[J]. 中国电机工程学报, 2014, 34(27): 4706-4716.
Fu Yuan, Wang Yi, Zhang Xiangyu, et al.Analysis and integrated control of inertia and primary frequency regulation for variable speed wind turbines[J]. Proceedings of the CSEE, 2014, 34(27): 4706-4716.
[2] 方勇杰. 英国“8·9”停电事故对频率稳定控制技术的启示[J]. 电力系统自动化, 2019, 43(24): 1-5.
Fang Yongjie.Reflections on frequency stability control technology based on the blackout event of 9 August 2019 in UK[J]. Automation of Electric Power Systems, 2019, 43(24): 1-5.
[3] 孙华东, 王宝财, 李文锋, 等. 高比例电力电子电力系统频率响应的惯量体系研究[J]. 中国电机工程学报, 2020, 40(16): 5179-5192.
Sun Huadong, Wang Baocai, Li Wenfeng, et al.Research on inertia system of frequency response for power system with high penetration electronics[J]. Proceedings of the CSEE, 2020, 40(16): 5179-5192.
[4] 池志坤, 袁至, 李骥. 基于系统频率与SOC状态预测的储能一次调频控制策略[J]. 高电压技术, 2025, 51(11): 5423-5434.
Chi Zhikun, Yuan Zhi, Li Ji.Primary frequency regulation control strategy of energy storage based on prediction of system frequency and state of charge[J]. High Voltage Engineering, 2025, 51(11): 5423-5434.
[5] Ramírez M, Castellanos R, Calderón G, et al.Placement and sizing of battery energy storage for primary frequency control in an isolated section of the Mexican power system[J]. Electric Power Systems Research, 2018, 160: 142-150.
[6] 刘闯, 孙同, 蔡国伟, 等. 基于同步机三阶模型的电池储能电站主动支撑控制及其一次调频贡献力分析[J]. 中国电机工程学报, 2020, 40(15): 4854-4866.
Liu Chuang, Sun Tong, Cai Guowei, et al.Third-order synchronous machine model based active support control of battery storage power plant and its contribution analysis for primary frequency response[J]. Proceedings of the CSEE, 2020, 40(15): 4854-4866.
[7] Knap V, Chaudhary S, Stroe D I, et al.Sizing of an energy storage system for grid inertial response and primary frequency reserve[J]. IEEE Transactions on Power Systems, 2016, 31(5): 3447-3456.
[8] 邓霞, 孙威, 肖海伟. 储能电池参与一次调频的综合控制方法[J]. 高电压技术, 2018, 44(4): 1157-1165.
Deng Xia, Sun Wei, Xiao Haiwei.Integrated control strategy of battery energy storage system in primary frequency regulation[J]. High Voltage Engineering, 2018, 44(4): 1157-1165.
[9] 李军徽, 侯涛, 穆钢, 等. 基于权重因子和荷电状态恢复的储能系统参与一次调频策略[J]. 电力系统自动化, 2020, 44(19): 63-72.
Li Junhui, Hou Tao, Mu Gang, et al.Primary frequency regulation strategy with energy storage system based on weight factors and state of charge recovery[J]. Automation of Electric Power Systems, 2020, 44(19): 63-72.
[10] 马智慧, 李欣然, 谭庄熙, 等. 考虑储能调频死区的一次调频控制方法[J]. 电工技术学报, 2019, 34(10): 2102-2115.
Ma Zhihui, Li Xinran, Tan Zhuangxi, et al.Integrated control of primary frequency regulation considering dead band of energy storage[J]. Transactions of China Electrotechnical Society, 2019, 34(10): 2102-2115.
[11] 吴启帆, 宋新立, 张静冉, 等. 电池储能参与电网一次调频的自适应综合控制策略研究[J]. 电网技术, 2020, 44(10): 3829-3836.
Wu Qifan, Song Lixin, Zhang Jingran, et al.Study on self-adaptation comprehensive strategy of battery energy storage in primary frequency regulation of power grid[J]. Power System Technology, 2020, 44(10): 3829-3836.
[12] 梁继业, 袁至, 王维庆, 等. 基于电池储能系统的综合自适应一次调频策略[J]. 电工技术学报, 2025, 40(7): 2322-2334.
Liang Jiye, Yuan Zhi, Wang Weiqing, et al.Comprehensive adaptive primary frequency control strategy based on battery energy storage system[J]. Transactions of China Electrotechnical Society, 2025, 40(7): 2322-2334.
[13] 付媛, 万怿, 张祥宇, 等. 储能虚拟惯量主动支撑与调频状态转移控制[J]. 中国电机工程学报, 2024, 44(7): 2628-2641.
Fu Yuan, Wan Yi, Zhang Xiangyu, et al.Energy storage virtual inertia active support and frequency modulation state transfer control[J]. Proceedings of the CSEE, 2024, 44(7): 2628-2641.
[14] 刘巨, 姚伟, 文劲宇, 等. 一种基于储能技术的风电场虚拟惯量补偿策略[J]. 中国电机工程学报, 2015, 35(7): 1596-1605.
Liu Ju, Yao Wei, Wen Jinyu, et al.A wind farm virtual inertia compensation strategy based on energy storage system[J]. Proceedings of the CSEE, 2015, 35(7): 1596-1605.
[15] 肖家杰, 李培强, 毛志宇, 等. 考虑火电时滞特性的电池储能集群调频综合控制策略研究[J]. 电工技术学报, 2025, 40(3): 689-704.
Xiao Jiajie, Li Peiqiang, Mao Zhiyu, et al.Research on integrated control strategy of battery energy storage cluster for frequency regulation considering thermal power time lag characteristic[J]. Transactions of China Electrotechnical Society, 2025, 40(3): 689-704.
[16] 高嵩, 李军, 宋辉, 等. 提升火电机组一次调频性能的火电-储能一体化系统研究[J]. 电力系统保护与控制, 2023, 51(21): 116-125.
Gao Song, Li Jun, Song Hui, et al.An integrated thermal power-energy storage system for improving primary frequency regulation performance of thermal power units[J]. Power System Protection and Control, 2023, 51(21): 116-125.
[17] 张小莲, 覃世球, 陈冲, 等. 考虑储能充放电均衡度的风储联合调频控制策略[J]. 电网技术, 2024, 48(05): 1938-1946.
Zhang Xiaolian, Qin Shiqiu, Chen Chong, et al.Wind turbine storage joint frequency modulation control strategy considering the balance of energy storage charge and discharge[J]. Power System Technology, 2024, 48(05): 1938-1946.
[18] 赵晶晶, 李敏, 何欣芹, 等. 基于限转矩控制的风储联合调频控制策略[J]. 电工技术学报, 2019, 34(23): 4982-4990.
Zhao Jingjing, Li Min, He Xinqin, et al.Coordinated control strategy of wind power and energy storage in frequency regulation based on torque limit control[J]. Transactions of China Electrotechnical Society, 2019, 34(23): 4982-4990.
[19] Johnson V H, Sack T.Temperature-dependent battery models for high-power lithium-ion batteries[J]. Office of Scientific & Technical Information Technical Reports, 2001.
[20] Lu Xiaonan, Sun Kai, Guerrero J M, et al.State-of-charge balance using adaptive droop control for distributed energy storage systems in DC microgrid applications[J]. IEEE Transactions on Industrial Electronics, 2013, 61(6): 2804-2815.
[21] Li Chendan, Coelho E A A, Dragicevic T, et al. Multiagent-based distributed state of charge balancing control for distributed energy storage units in AC microgrids[J]. IEEE Transactions on Industry Applications, 2017, 53(3): 2369-2381.
[22] Kundur P.Power System Stability and Control[M]. 北京: 中国电力出版社, 1994.
[23] Huang Ziyang, Wang Zihan, Zhang Xiaonan, et al.Dynamic frequency regulation of wind turbine generators via kinetic energy trajectory-based control[J]. CSEE Journal of Power and Energy Systems, 2026, 12(2): 698-711.