PSO-optimized sensor-less sliding mode control for variable speed wind turbine chains based on DPIG with neural-MRAS observer

IF 1.5 Q4 ENERGY & FUELS

Wind Engineering Pub Date : 2024-07-27 DOI:10.1177/0309524x241263591

L. Saihi, F. Ferroudji, K. Roummani, K. Koussa, L. Djilali

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引用次数: 0

Abstract

This research introduces a resilient Sensor-Less 1st Sliding Mode (SL-FOSM) approach employing a novel observer, the Artificial Neural Network with Model Reference Adaptive System-Adaptive (Neural-MRAS), for wind turbine chains. The proposed model is implemented on a Doubly Powered Induction Generator (DPIG) operating under genuine variable speed conditions in the Adrar region in Algeria. The control objective is to independently regulate the active and reactive power of the DPIG stator, achieved through decoupling using the field-oriented control technique and control application via FOSM-C. Notably, this methodology reduces both the control scheme cost and the DPIG size by eliminating the need for a speed sensor (encoder). To enhance the MRAS-PI, an Artificial Neural Network (ANN) is suggested to replace the typical classical Proportional-Integral (PI) controller in the adaptation mechanism of MRAS. The rotor position estimation is scrutinized and discussed across various load conditions in low, zero, and high-speed regions. Optimal controller parameters are determined through particle swarm optimization (PSO). The results demonstrate that the proposed observer (Neural-MRAS) exhibits compelling attributes, including guaranteed finite time convergence, robust performance in response to speed variations, high resilience against machine parameter fluctuations, and adaptability to load variations when compared to the MRAS-PI. Consequently, the estimated rotor speed converges to its actual value, showcasing the capability to accurately estimate position across different speed regions (low/zero/high).

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基于 DPIG 与神经-MRAS 观察器的变速风力涡轮机链 PSO 优化无传感器滑模控制

本研究为风力涡轮机链引入了一种弹性无传感器第一滑动模式（SL-FOSM）方法，该方法采用了一种新型观测器--人工神经网络与模型参考自适应系统（Neural-MRAS）。提出的模型在阿尔及利亚阿德拉尔地区真正变速条件下运行的双电源感应发电机（DPIG）上实现。控制目标是独立调节 DPIG 定子的有功功率和无功功率，通过使用面向现场的控制技术和 FOSM-C 控制应用实现解耦。值得注意的是，这种方法不需要速度传感器（编码器），从而降低了控制方案的成本和 DPIG 的尺寸。为了增强 MRAS-PI，建议在 MRAS 的适应机制中使用人工神经网络（ANN）来替代典型的传统比例-积分（PI）控制器。在低速、零速和高速区域的各种负载条件下，对转子位置估计进行了仔细研究和讨论。通过粒子群优化（PSO）确定了最佳控制器参数。结果表明，与 MRAS-PI 相比，所提出的观测器（神经-MRAS）具有令人信服的特性，包括保证有限时间收敛性、响应速度变化的稳健性能、对机器参数波动的高适应性以及对负载变化的适应性。因此，估计的转子速度收敛到了实际值，展示了在不同速度区域（低速/零速/高速）准确估计位置的能力。

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

Wind Engineering ENERGY & FUELS-

CiteScore

4.00

自引率

13.30%

发文量

期刊介绍： Having been in continuous publication since 1977, Wind Engineering is the oldest and most authoritative English language journal devoted entirely to the technology of wind energy. Under the direction of a distinguished editor and editorial board, Wind Engineering appears bimonthly with fully refereed contributions from active figures in the field, book notices, and summaries of the more interesting papers from other sources. Papers are published in Wind Engineering on: the aerodynamics of rotors and blades; machine subsystems and components; design; test programmes; power generation and transmission; measuring and recording techniques; installations and applications; and economic, environmental and legal aspects.