基于扰动屏蔽与改进阿尔法算法的构网馈风电机组控制参数辨识

doi:10.19595/j.cnki.1000-6753.tces.250931

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摘要针对构网型双馈风力发电机组的控制参数辨识问题,该文提出一种在扰动屏蔽基础上,采用弹性网络结合改进阿尔法进化算法的参数辨识策略。首先通过弹性网络确定与控制参数关联性强的观测量,采用轨迹灵敏度分析法确定构网型双馈风力发电机（VSG-DFIG）参数的可区分辨识度,并对比分析一次侧短路法与扰动屏蔽法的灵敏度数值,验证扰动屏蔽策略的可行性。最后在扰动屏蔽策略的基础上,采用改进阿尔法进化算法结合多目标加权优化模型进行参数辨识。仿真结果表明,相比于基于一次侧短路故障的辨识策略,该文方法在多种工况下显著降低了计算成本,并提高了参数辨识的准确性,为构网型双馈风力发电机组的建模与控制提供了更精确的参数支撑。

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	贾博为
	张学广
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关键词 ：参数辨识, 扰动屏蔽, 多目标加权优化, 改进阿尔法进化算法, 轨迹灵敏度

Abstract：In China, power electronic equipment plays a key role in modern power grids thanks to its fast dynamic response ability. However, it lacks the unique stability characteristics of synchronous motors. Therefore, some scholars have proposed the concept of a virtual synchronous machine (VSG). Relying on this concept, the VSG-DFIG was developed. The converter plays a central role in the wind power generation system; its control parameters significantly impact the system's dynamic performance.
This paper proposes a parameter identification strategy for VSG-DFIG, based on disturbance shielding and multi-objective weighted summation. First, observations strongly correlated with the control parameters are identified through the elastic network, and these observations are then used as variables in the subsequent optimization objective function. Trajectory sensitivity analysis is used to distinguish the VSG-DFIG parameters, and the traditional primary-side short-circuit condition is compared with the disturbance shielding method. Finally, based on the disturbance shielding strategy, an improved α-coefficient evolutionary algorithm combined with a multi-objective weighted optimization model is used for parameter identification.
The following conclusions verify the effectiveness of the proposed method. (1) The sensitivity of the parameters of the multi-stage control in a primary-side short-circuit fault is coupled, making identification difficult. Shielding the disturbance at the first stage can significantly reduce the sensitivity of the controller parameters, considerably improving the accuracy of their identification. (2) Using an elastic network and a multi-objective weighting method to select the identification objective function improves the accuracy of identification. The convergence speed and accuracy of the improved AE algorithm are higher than the original AE algorithm. (3) Compared with the terminal voltage drop condition with the disturbance superposition condition, the proposed multi-objective weighted summation with the disturbance shielding strategy can effectively improve the identification accuracy and reliability of the control parameters of the VSG-DFIG.

Key words： Parameter identification disturbance shielding multi-objective weighted optimization improved alpha evolution algorithm trajectory sensitivity

收稿日期: 2025-06-03

PACS:

TM614

通讯作者: 张学广男,1981年生,教授,博士生导师,研究方向为风力发电技术。E-mail: zxghit@126.com

作者简介: 贾博为男,2001年生,硕士研究生,研究方向为新能源并网系统建模与控制。E-mail: 18849286248@163.com

引用本文:

贾博为, 张学广, 徐殿国. 基于扰动屏蔽与改进阿尔法算法的构网馈风电机组控制参数辨识[J]. 电工技术学报, 2026, 41(10): 3465-3481. Jia Bowei, Zhang Xueguang, Xu Dianguo. Control Parameter Identification of Grid-Forming Doubly-Fed Induction Generator Wind Turbines Based on Disturbance Shielding Improved Alpha Algorithm. Transactions of China Electrotechnical Society, 2026, 41(10): 3465-3481.

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