Muhammad Ishaque, Javed Ahmed Laghari, Muhammad Akram Bhayo, Sadullah Chandio, Ibrahim Mahariq
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However, implementing the PI controller alone with the WTPGS often suffers from high overshoot and sluggish response in nonlinear systems like WTPGS. In contrast, ANFIS controllers offer superior performance to PI and other artificial intelligence controllers but are still susceptible to noise issues. In this paper, the proposed WTPGS system is designed in MATLAB/Simulink software where a hybrid controller (ANFIS-PI) is implemented in the machine-side converter (MSC) and grid-side converter (GSC) of a variable speed PMSG-based wind turbine to enhance its performance subjected to wind variations. The hybrid controller is implemented in such a way that the ANFIS controller is implemented in the outer layers while the PI controller is applied in the inner layers of both MSC and GSC. The simulation results for this hybrid controller in the MSC outperform those of the conventional PI controller. 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引用次数: 0
摘要
本文介绍了一种新型混合控制器,该控制器专为使用永磁同步发电机(PMSG)的风力涡轮发电系统(WTPGS)而设计。这种混合控制器结合了自适应神经模糊推理系统 (ANFIS) 的适应性和比例积分 (PI) 控制器的简易性。PI 控制器传统上用于处理稳定性和噪音。ANFIS 增加了适应性,使其更适合应对风能的多变性。这种混合策略的主要目的是在遇到连续多变的风力条件时,提高基于 PMSG 的 WTPGS 的整体控制性能和可靠性。然而,在 WTPGS 等非线性系统中,单独使用 PI 控制器往往会出现高过冲和响应迟缓的问题。相比之下,ANFIS 控制器的性能优于 PI 控制器和其他人工智能控制器,但仍容易受到噪声问题的影响。本文在 MATLAB/Simulink 软件中设计了拟议的 WTPGS 系统,在基于 PMSG 的变速风力涡轮机的机侧变流器(MSC)和电网侧变流器(GSC)中实施了混合控制器(ANFIS-PI),以提高其在风力变化下的性能。混合控制器的实施方式是,在 MSC 和 GSC 的外层实施 ANFIS 控制器,在内层实施 PI 控制器。这种混合控制器在 MSC 中的仿真结果优于传统的 PI 控制器。它们显示出最小的过冲和稳定时间,即使在不同时间间隔内受到各种测试信号的影响,也能保持稳定。同样,GSC 也超越了传统的 PI 控制器,最大过冲显著降低了 6.4%,平稳时间缩短了 4.36 秒。这凸显了其在风力涡轮机应用中的强大适用性。
Hybrid ANFIS-PI-Based Robust Control of Wind Turbine Power Generation System
This paper introduces a novel hybrid controller designed for a wind turbine power generation system (WTPGS) that utilizes a permanent magnet synchronous generator (PMSG). This hybrid controller combines the adaptability of an adaptive neuro-fuzzy inference system (ANFIS) with the simplicity of a proportional-integral (PI) controller. The PI controllers are traditionally used for stability and noise handling. ANFIS adds adaptability, making it more suitable to cope with the variable nature of wind energy. The primary objective of this hybrid strategy is to augment the overall control performance and reliability of PMSG-based WTPGS when encountered with continuous variable wind conditions. However, implementing the PI controller alone with the WTPGS often suffers from high overshoot and sluggish response in nonlinear systems like WTPGS. In contrast, ANFIS controllers offer superior performance to PI and other artificial intelligence controllers but are still susceptible to noise issues. In this paper, the proposed WTPGS system is designed in MATLAB/Simulink software where a hybrid controller (ANFIS-PI) is implemented in the machine-side converter (MSC) and grid-side converter (GSC) of a variable speed PMSG-based wind turbine to enhance its performance subjected to wind variations. The hybrid controller is implemented in such a way that the ANFIS controller is implemented in the outer layers while the PI controller is applied in the inner layers of both MSC and GSC. The simulation results for this hybrid controller in the MSC outperform those of the conventional PI controller. They demonstrate minimal overshooting and settling time, maintaining consistent stability even when subjected to various test signals at different intervals. Similarly, the GSC also surpasses conventional PI controllers, achieving a significant 6.4% reduction in maximum overshoot and a decrease of 4.36 seconds in settling time. This highlights its strong suitability for wind turbine applications.
期刊介绍:
International Transactions on Electrical Energy Systems publishes original research results on key advances in the generation, transmission, and distribution of electrical energy systems. Of particular interest are submissions concerning the modeling, analysis, optimization and control of advanced electric power systems.
Manuscripts on topics of economics, finance, policies, insulation materials, low-voltage power electronics, plasmas, and magnetics will generally not be considered for review.