{"title":"风力发电系统优化和控制中的 PI(2DoF)算法概述","authors":"Belachew Desalegn, Bimrew Tamrat","doi":"10.3389/fenrg.2024.1435455","DOIUrl":null,"url":null,"abstract":"Recent research generally reports that the intermittent characteristics of sustainable energy sources pose great challenges to the efficiency and cost competitiveness of sustainable energy harvesting technologies. Hence, modern sustainable energy systems need to implement a stringent power management strategy to achieve the maximum possible green electricity production while reducing costs. Due to the above-mentioned characteristics of sustainable energy sources, power management systems have become increasingly sophisticated nowadays. For addressing the analysis, scheduling, and control problems of future sustainable power systems, conventional model-based methods are completely inefficient as they fail to handle irregular electric power disturbances in renewable energy generations. Consequently, with the advent of smart grids in recent years, power system operators have come to rely on smart metering and advanced sensing devices for collecting more extensive data. This, in turn, facilitates the application of advanced machine learning algorithms, which can ultimately cause the generation of useful information by learning from massive data without assumptions and simplifications in handling the most irregular operating behaviors of the power systems. This paper aims to explore various application objectives of some machine learning algorithms that primarily apply to wind energy conversion systems (WECSs). In addition, an enhanced proportional integral (PI) (2DoF) algorithm is particularly introduced and implemented in a doubly fed induction generator (DFIG)-based WECS to enhance the reliability of power production. The main contribution of this article is to leverage the superior qualities of the PI (2DoF) algorithm for enhanced performance, stability, and robustness of the WECS under uncertainties. 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引用次数: 0
摘要
最近的研究普遍报告称,可持续能源的间歇性特点对可持续能源采集技术的效率和成本竞争力提出了巨大挑战。因此,现代可持续能源系统需要实施严格的电源管理策略,在降低成本的同时实现最大可能的绿色电力生产。鉴于可持续能源的上述特点,如今的电力管理系统已变得越来越复杂。在解决未来可持续电力系统的分析、调度和控制问题时,传统的基于模型的方法因无法处理可再生能源发电中的不规则电力干扰而效率低下。因此,随着近年来智能电网的出现,电力系统运营商开始依赖智能计量和先进的传感设备来收集更广泛的数据。这反过来又促进了先进机器学习算法的应用,通过从海量数据中学习,最终生成有用的信息,而无需假设和简化处理电力系统最不规则的运行行为。本文旨在探讨一些主要适用于风能转换系统(WECS)的机器学习算法的各种应用目标。此外,本文还特别介绍了一种增强型比例积分(PI)(2DoF)算法,并在基于双馈异步发电机(DFIG)的风能转换系统中加以应用,以提高电力生产的可靠性。本文的主要贡献在于利用 PI (2DoF) 算法的优越性来提高 WECS 在不确定情况下的性能、稳定性和鲁棒性。最后,通过在 MATLAB-Simulink 环境中开发虚拟现实,证明了该研究的有效性。
Overview of the PI (2DoF) algorithm in wind power system optimization and control
Recent research generally reports that the intermittent characteristics of sustainable energy sources pose great challenges to the efficiency and cost competitiveness of sustainable energy harvesting technologies. Hence, modern sustainable energy systems need to implement a stringent power management strategy to achieve the maximum possible green electricity production while reducing costs. Due to the above-mentioned characteristics of sustainable energy sources, power management systems have become increasingly sophisticated nowadays. For addressing the analysis, scheduling, and control problems of future sustainable power systems, conventional model-based methods are completely inefficient as they fail to handle irregular electric power disturbances in renewable energy generations. Consequently, with the advent of smart grids in recent years, power system operators have come to rely on smart metering and advanced sensing devices for collecting more extensive data. This, in turn, facilitates the application of advanced machine learning algorithms, which can ultimately cause the generation of useful information by learning from massive data without assumptions and simplifications in handling the most irregular operating behaviors of the power systems. This paper aims to explore various application objectives of some machine learning algorithms that primarily apply to wind energy conversion systems (WECSs). In addition, an enhanced proportional integral (PI) (2DoF) algorithm is particularly introduced and implemented in a doubly fed induction generator (DFIG)-based WECS to enhance the reliability of power production. The main contribution of this article is to leverage the superior qualities of the PI (2DoF) algorithm for enhanced performance, stability, and robustness of the WECS under uncertainties. Finally, the effectiveness of the study is demonstrated by developing a virtual reality in a MATLAB-Simulink environment.