IPC‐based robust disturbance accommodating control for load mitigation and speed regulation of wind turbines

IF 5.4 3区材料科学 Q2 CHEMISTRY, PHYSICAL

ACS Applied Energy Materials Pub Date : 2024-01-10 DOI:10.1002/we.2893

Edwin Kipchirchir, D. Söffker

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引用次数: 0

Abstract

Over the past few decades, global demand for renewable energy has been rising steadily. To meet this demand, there has been an exponential growth in size of wind turbines (WTs) to capture more energy from wind. Consequent increase in weight and flexibility of WT components has led to increased structural loading, affecting reliability of these wind energy conversion systems. Spatio‐temporal variation of rotor effective wind field acts as a disturbance to a WT system, hence, necessitating controllers that can cancel this disturbance. Additionally, assumptions made in extracting linear models for controller design lead to modeling errors resulting from changing operating conditions. Previous attempts have proposed robust controllers incorporating wind disturbance models. However, these controllers have been evaluated on smaller WTs, which experience lower structural loading than larger ones. Additionally, a majority these controllers are based on collective pitch control (CPC), hence do not address loading in the blades. To address these challenges, this contribution proposes an independent pitch‐based robust disturbance accommodating controller (IPC‐RDAC) for reducing structural loads and regulating generator speed in utility‐scale WTs. The proposed controller is designed using ‐synthesis approach and is evaluated on the 5 MW National Renewable Energy Laboratory (NREL) reference WT. Its performance is evaluated against a gain‐scheduled proportional integral (GSPI)‐based reference open‐source controller (ROSCO) and a CPC‐based RDAC (CPC‐RDAC) controller, developed previously by the authors. Simulation results for various wind conditions show that the proposed controller offers improved performance in blade and tower load mitigation, as well a generator speed regulation.

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基于 IPC 的鲁棒扰动适应控制，用于风力涡轮机的负载缓解和速度调节

过去几十年来，全球对可再生能源的需求一直在稳步上升。为满足这一需求，风力涡轮机（WT）的体积呈指数级增长，以便从风力中获取更多能量。风力涡轮机部件的重量和灵活性随之增加，导致结构载荷增加，影响了这些风能转换系统的可靠性。转子有效风场的时空变化对 WT 系统构成干扰，因此需要能消除这种干扰的控制器。此外，在为控制器设计提取线性模型时所作的假设会导致因运行条件变化而产生的建模误差。之前的尝试提出了包含风扰动模型的鲁棒控制器。不过，这些控制器都是在较小的风电机组上进行评估的，因为较小的风电机组比较大的风电机组承受的结构负荷要小。此外，这些控制器大多基于集合变桨控制（CPC），因此无法解决叶片负载问题。为了应对这些挑战，本文提出了一种基于独立变桨的鲁棒扰动适应控制器（IPC-RDAC），用于降低公用事业级风电机组的结构负载和调节发电机转速。该控制器采用合成法设计，并在美国国家可再生能源实验室（NREL）的 5 兆瓦参考风电机组上进行了评估。其性能对照作者之前开发的基于增益调度比例积分（GSPI）的参考开源控制器（ROSCO）和基于 CPC 的 RDAC（CPC-RDAC）控制器进行了评估。各种风况下的仿真结果表明，所提出的控制器在叶片和塔架负载缓解以及发电机调速方面的性能都有所提高。

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

ACS Applied Energy Materials Materials Science-Materials Chemistry

CiteScore

10.30

自引率

6.20%

发文量

1368

期刊介绍： ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.