Research Article
Robust Control System for DFIG-Based WECS and Energy Storage in reel Wind Conditions
@ARTICLE{10.4108/ew.4856, author={Chojaa Hamid and Derouich Aziz and Othmane Zamzoum and Abderrahman El Idrissi}, title={Robust Control System for DFIG-Based WECS and Energy Storage in reel Wind Conditions}, journal={EAI Endorsed Transactions on Energy Web}, volume={11}, number={1}, publisher={EAI}, journal_a={EW}, year={2024}, month={1}, keywords={Backstepping control, Doubly-Fed Induction Generator, DFIG, Storage System, WECS}, doi={10.4108/ew.4856} }
- Chojaa Hamid
Derouich Aziz
Othmane Zamzoum
Abderrahman El Idrissi
Year: 2024
Robust Control System for DFIG-Based WECS and Energy Storage in reel Wind Conditions
EW
EAI
DOI: 10.4108/ew.4856
Abstract
This research work focuses on addressing the challenges of controlling a wind energy conversion system (WECS) connected to the grid, particularly when faced with variable wind speed profiles. The system consists of a Doubly-Fed Induction Generator (DFIG) connected to the grid through an AC/DC/AC converter, along with a Li-ion battery storage system connected to the Back-to-Back converter DC link via a DC/DC converter. The non-linearity and internal parametric variation of the wind turbine can negatively impact energy production, battery charging performance, and battery lifespan. To overcome these issues, the study proposes a robust control approach called Integral action Sliding Mode Control (ISMC) to enhance the dynamic performance of the WECS based on DFIG. Additionally, the battery charging and discharging controllers play a crucial role in efficiently distributing power to the grid and storage unit based on the battery's state of charge, extracted energy, and power injected into the grid. Two current regulation modes, buck charging and boost discharging, are employed to ensure proper energy distribution. Furthermore, a storage system energy management algorithm is implemented to ensure battery safety during one of the charging modes. The effectiveness and robustness of the proposed control method were validated through simulations of a 1.5 MW wind power conversion system using Matlab/Simulink. The results confirmed the method's efficiency and efficacy.
Copyright © 2024 C. Hamid et al., licensed to EAI. This is an open access article distributed under the terms of the CC BY-NC-SA 4.0, which permits copying, redistributing, remixing, transformation, and building upon the material in any medium so long as the original work is properly cited.