Advanced control strategy for AC microgrids: a hybrid ANN-based adaptive PI controller with droop control and virtual impedance technique

被引:3
作者
Adiche, Sarra [1 ]
Larbi, Mhamed [1 ]
Toumi, Djilali [1 ]
Bouddou, Riyadh [2 ]
Bajaj, Mohit [3 ,4 ,5 ]
Bouchikhi, Nasreddine [2 ,6 ]
Belabbes, Abdallah [7 ]
Zaitsev, Ievgen [8 ,9 ]
机构
[1] Univ Tiaret, Dept Elect Engn, L2GEGI Lab, Tiaret 14000, Algeria
[2] Univ Ctr Naama, Inst Technol, Dept Elect Engn, Naama 45000, Algeria
[3] Grap Era Deemed Univ, Dept Elect Engn, Dehra Dun 248002, India
[4] AL Ahliyya Amman Univ, Hourani Ctr Appl Sci Res, Amman, Jordan
[5] Univ Business & Technol, Coll Engn, Jeddah 21448, Saudi Arabia
[6] Univ Setif 1, Dept Elect Engn, Setif, Algeria
[7] Univ Oran 2 Mohammed Ben Ahmed, Inst Maintenance & Ind Safety, Oran, Algeria
[8] Natl Acad Sci Ukraine, Inst Electrodynam, Dept Theoret Elect Engn & Diagnost Elect Equipment, Beresteyskiy 56, UA-03680 Kiev 57, Ukraine
[9] Natl Acad Sci Ukraine, Ctr Informat Analyt & Tech Support Nucl Power Faci, Akademika Palladina Ave 34-A, Kiev, Ukraine
来源
SCIENTIFIC REPORTS | 2024年 / 14卷 / 01期
关键词
AC microgrids; Adaptive PI controller; Artificial neural network; Droop control; Virtual impedance technique; Total harmonic distortion reduction; Distributed generators; Voltage regulation; DISTRIBUTED ENERGY MANAGEMENT; VOLTAGE CONTROL STRATEGY; POWER QUALITY; PHOTOVOLTAIC SYSTEMS; GRID INTEGRATION; OPERATION; STORAGE; OPTIMIZATION; PERFORMANCE; STABILITY;
D O I
10.1038/s41598-024-82193-1
中图分类号
O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];
学科分类号
07 ; 0710 ; 09 ;
摘要
In this paper, an improved voltage control strategy for microgrids (MG) is proposed, using an artificial neural network (ANN)-based adaptive proportional-integral (PI) controller combined with droop control and virtual impedance techniques (VIT). The control strategy is developed to improve voltage control, power sharing and total harmonic distortion (THD) reduction in the MG systems with renewable and distributed generation (DG) sources. The VIT is used to decouple active and reactive power, reduce negative power interactions between DG's and improve the robustness of the system under varying load and generation conditions. Simulation findings under different tests have shown significant improvements in performance and computational simulation. The rise time is reduced by 60%, the overshoot is reduced by 80%, the THD of the voltage is reduced by 75% (from 0.99 to 0.20%), and the THD of the current is reduced by 69% (from 10.73 to 3.36%) compared to the conventional PI controller technique. Furthermore, voltage and current THD values were maintained below the IEEE-519 standard limits of 5% and 8%, respectively, for the power quality enhancement. Fluctuations in voltage and frequency were also maintained at 2% tolerance and 1% tolerance, respectively, across all voltage limits, which is consistent with international norms. Power-sharing errors were reduced by 50% after conducting the robustness tests against the DC supply and load disturbances. In addition, the proposed strategy outperforms the previous control techniques presented at the state of the art in terms of adaptability, stability and, especially, the ability to reduce the THD, which validates its effectiveness for MG systems control and optimization under uncertain conditions.
引用
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页数:44
相关论文
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