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基于多源传感器数据的增强型人工蜂群算法的风电场与电池储能系统模糊控制参数优化

Optimization of Fuzzy Control Parameters for Wind Farms and Battery Energy Storage Systems Based on an Enhanced Artificial Bee Colony Algorithm under Multi-Source Sensor Data.

作者信息

Liu Zejian, Yang Ping, Zhang Peng, Lin Xu, Wei Jiaxi, Li Ning

机构信息

Key Laboratory of Clean Energy Technology of Guangdong Province, School of Electric Power Engineering, South China University of Technology, Guangzhou 510640, China.

Shenzhen Huagong Energy Technology Co., Ltd., Shenzhen 518066, China.

出版信息

Sensors (Basel). 2024 Aug 7;24(16):5115. doi: 10.3390/s24165115.

DOI:10.3390/s24165115
PMID:39204814
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11360808/
Abstract

With the rapid development of sensors and other devices, precise control for the generation of new energy, especially in the context of highly stochastic wind power generation, has been strongly supported. However, large-scale wind farm grid connection can cause the power system to enter a low inertia state, leading to frequency instability. Battery energy storage systems (BESSs) have the advantages of a fast response speed and high flexibility, and can be applied to wind farm systems to improve the frequency fluctuation problem in the process of grid connection. To address the frequency fluctuation problem caused by the parameter error of the fuzzy membership function in the fuzzy control of a doubly fed induction generator (DFIG) and a BESS, this paper proposes an improved Artificial Bee Colony (ABC) algorithm based on multi-source sensor data for optimizing the fuzzy controller to improve the frequency control ability of BESSs and DFIGs. A Gaussian wandering mechanism was introduced to improve the ABC algorithm and enhance the convergence speed of the algorithm, and the improved ABC algorithm was optimized for the selection of fuzzy control affiliation function parameters to improve the frequency response performance. The effectiveness of the proposed control strategy was verified on the MATLAB/Simulink simulation platform. After optimization using the proposed control strategy, the oscillation amplitude was reduced by 0.15 Hz, the precision was increased by 40%, and the steady-state frequency deviation was reduced by 26%. The results show that the method proposed in this paper provides a great improvement in the frequency stability of coordinated systems of wind farms and BESSs.

摘要

随着传感器及其他设备的快速发展,对新能源发电的精确控制得到了有力支持,尤其是在高度随机的风力发电背景下。然而,大规模风电场并网会导致电力系统进入低惯性状态,从而引发频率不稳定。电池储能系统(BESS)具有响应速度快和灵活性高的优点,可应用于风电场系统以改善并网过程中的频率波动问题。为解决双馈感应发电机(DFIG)与BESS模糊控制中模糊隶属函数参数误差引起的频率波动问题,本文提出一种基于多源传感器数据的改进人工蜂群(ABC)算法,用于优化模糊控制器,以提高BESS和DFIG的频率控制能力。引入高斯游荡机制改进ABC算法,提高算法收敛速度,并针对模糊控制隶属函数参数选择对改进的ABC算法进行优化,以改善频率响应性能。在MATLAB/Simulink仿真平台上验证了所提控制策略的有效性。采用所提控制策略优化后,振荡幅度降低了0.15Hz,精度提高了40%,稳态频率偏差降低了26%。结果表明,本文提出的方法在风电场与BESS协调系统的频率稳定性方面有很大提升。

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