Artificial intelligence-based direct power control for power quality improvement in a WT-DFIG system via neural networks: Prediction and classification techniques

IF 3.7 3区 计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS
Karim Fathi Sayeh , Salah Tamalouzt , Younes Sahri , Sofia Lalouni Belaid , Abdellah Bekhiti
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Abstract

This paper discusses the improvement of power quality injected into the AC grid. This approach is achieved by enhancing the quality of injected power signals and mastering the active and reactive power exchanged between the DFIG based wind turbine (WT-DFIG) and the electrical grid, resulting in an improvement of the overall system performance and efficiency. This study includes all WT-DFIG operating modes, successively and continuously, as well as all local reactive power compensation modes. Therefore, novel control strategies are proposed in this paper for wind energy conversion systems based on artificial intelligence techniques. These techniques include Neural Network Prediction (PNN-DPC) and Classification (CNN-DPC). They aim to eliminate the drawbacks and difficulties associated with conventional Direct Power Control (C-DPC), while retaining its advantages. The paper also provides a thorough explanation of the mathematical models for neural network techniques and WT-DFIG system models. The MATLAB/Simulink environment is used to investigate the performance of the proposed techniques under different conditions and operating modes related to different scenarios. The results reveal a significant reduction in the ripple of the generated active power and the compensated local reactive power, better quality of the generated signal currents and a remarkable reduction in the current total harmonic distortion (THD). Furthermore, compared to C-DPC, PNN-DPC achieves a reduction of 72.07 % in active power ripples, 77.07 % in reactive power ripples, and 76.79 % in current Total Harmonic Distortion (THD). CNN-DPC shows similar improvements with 72.04 %, 77.13 %, and 76.54 % of reductions respectively. In addition, CNN-DPC slightly outperforms PNN-DPC. Nevertheless, both proposed control techniques show significant improvements in all characteristics compared to other methods. Consequently, the proposed control strategies indicate that artificial intelligence has the potential to improve the power quality and performance of wind power conversion system.
基于人工智能的直接功率控制,通过神经网络改善 WT-DFIG 系统的电能质量:预测和分类技术
本文讨论了如何提高注入交流电网的电能质量。这种方法是通过提高注入功率信号的质量,掌握基于双馈风力发电机组(WT-DFIG)和电网之间交换的有功和无功功率,从而提高整个系统的性能和效率。这项研究包括所有 WT-DFIG 运行模式(连续和连续)以及所有本地无功功率补偿模式。因此,本文提出了基于人工智能技术的风能转换系统新型控制策略。这些技术包括神经网络预测(PNN-DPC)和分类(CNN-DPC)。它们旨在消除与传统直接功率控制(C-DPC)相关的缺点和困难,同时保留其优点。本文还对神经网络技术的数学模型和 WT-DFIG 系统模型进行了详尽的解释。本文使用 MATLAB/Simulink 环境研究了所提技术在不同条件和运行模式下的性能。结果显示,产生的有功功率和补偿的本地无功功率的纹波明显减少,产生的信号电流质量更好,电流总谐波失真(THD)显著降低。此外,与 C-DPC 相比,PNN-DPC 有功功率纹波降低了 72.07%,无功功率纹波降低了 77.07%,电流总谐波失真 (THD) 降低了 76.79%。CNN-DPC 也有类似的改进,分别降低了 72.04%、77.13% 和 76.54%。此外,CNN-DPC 略微优于 PNN-DPC。不过,与其他方法相比,这两种建议的控制技术在所有特性上都有显著改善。因此,所提出的控制策略表明,人工智能具有改善风能转换系统电能质量和性能的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.30
自引率
14.60%
发文量
586
审稿时长
6.9 months
期刊介绍: The Journal of The Franklin Institute has an established reputation for publishing high-quality papers in the field of engineering and applied mathematics. Its current focus is on control systems, complex networks and dynamic systems, signal processing and communications and their applications. All submitted papers are peer-reviewed. The Journal will publish original research papers and research review papers of substance. Papers and special focus issues are judged upon possible lasting value, which has been and continues to be the strength of the Journal of The Franklin Institute.
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