A novel intelligent control approach for wind energy conversion systems with synchronous reluctance generators

Selma, Belkacem; Bounadja, Elhadj; Belmadani, Bachir; Selma, Boumediene; Fliess, Michel

doi:10.1002/cta.3958

Circuit Theory & Apps

2024

DOI: 10.1002/cta.3958

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A novel intelligent control approach for wind energy conversion systems with synchronous reluctance generators

Belkacem Selma,

Elhadj Bounadja,

Bachir Belmadani

et al.

Abstract: SummaryThis study addresses a significant research gap in the field of wind energy, focusing on the underutilized potential of synchronous reluctance generators (SynRG) in wind power conversion systems (WPCS). Despite notable advancements in wind energy controls, the capabilities of SynRG within these systems have not been fully explored. In response, we introduce an innovative model‐free control (MFC) approach, termed intelligent proportional (iP), specifically designed and optimized for WPCS equipped with Sy… Show more

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Cited by 4 publications

References 65 publications

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Modified third‐order sliding mode control with adaptive gains for a multiphase PMSG wind turbine under double‐phase open fault

Bounadja,

Belhadj Djilali,

Yahdou

2024

Circuit Theory & Apps

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Wind energy production systems (WEPS) are increasingly vital in the transition to renewable energy sources, with permanent magnetic synchronous generators (PMSG) being widely adopted due to their high efficiency and reliability. Developing robust control methods is essential to ensure that WEPS operate efficiently even under adverse conditions. This study focuses on optimizing control strategies for WEPS utilizing a 5‐phase PMSG and addresses challenges posed by double‐phase open fault (DPOF) scenarios. Unlike conventional second‐order sliding mode control (SOSMC) based on the super‐twisting algorithm (STA), the proposed method enhances performance by elevating the sliding surface time derivative degree to a third order and modifying the discontinuous term of STA with an arctangent function, promising to reduce chattering effects. Additionally, an adaptation law adjusts the improved STA gains, forming adaptive‐gain third‐order sliding mode control (AG‐TOSMC), which outperforms SOSMC under various disturbances such as wind speed fluctuations, parameter changes, and DPOF scenarios. The AG‐TOSMC enhances the quality of active and reactive power by reducing fluctuation ratios compared with the SOSMC. The efficiency of WEPS increases to 98.5% with AG‐TOSMC, surpassing the 93.5% achieved with SOSMC. Additionally, a DPOF test confirms the aptitude of the 5‐phase PMSG to work under degraded circumstances, supplying appropriate electrical power to the network without significant adverse effects. Numerical simulations validate the efficiency of the suggested WEPS and its control, demonstrating superior performance achieved with AG‐TOSMC.

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Modified third‐order sliding mode control with adaptive gains for a multiphase PMSG wind turbine under double‐phase open fault

Bounadja,

Belhadj Djilali,

Yahdou

2024

Circuit Theory & Apps

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A Novel Approach of Nonlinear Control in Photovoltaic/Wind/Energy Storage System With Event‐Triggered DC Link Voltage Control in DC Microgrid

Alankrita,

Pati,

Adhikary

2024

Circuit Theory & Apps

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A hybrid DC microgrid (DC MG) integrates diverse renewable energy sources (RESs), each exhibiting unique nonlinear generation and power response characteristics. The intrinsic nonlinearity of these interacting RES necessitates the design of nonlinear control strategies to ensure stable operation and reliable power supply within the DC MG system. This paper presents a novel approach for nonlinear control of DC link voltage in hybrid DC MGs. Hybrid backstepping‐based controllers with event‐triggered (ET) control are proposed to enhance the energy quality produced by the DC MG during multiple disturbances while minimizing stress on converters by reducing the frequency of trigger signals. The PV controller is designed to maintain stability amid fluctuations in cell temperature and variations in solar irradiation. The wind controller is optimized for efficient wind power extraction, ensuring high performance in both static and dynamic conditions. The ESS is coordinated to mitigate constraints associated with RESs. Additionally, an ET controller is implemented for DC link voltage control, improving channel bandwidth efficiency and reducing strain on converters. This leads to longer interevent intervals compared with other nonlinear controllers, minimizing the need for frequent control adjustments. Lyapunov stability analysis is performed on the controllers to guarantee the asymptotic stability of the closed‐loop system. The proposed control schemes are then validated through numerical simulations in MATLAB/Simulink and further tested on an OPAL‐RT real‐time simulator. The results demonstrate that the proposed scheme improves coordination challenges among multiple RESs under uncertainties while also lowering computational overhead compared with traditional control methods.

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A New Third-Order Continuous Sliding Mode Speed and DC-Link Voltage Controllers for a PMSG-based Wind Turbine with Energy Storage System

Bounadja,

Yahdou,

Kacemi

et al. 2024

Arab J Sci Eng

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A novel intelligent control approach for wind energy conversion systems with synchronous reluctance generators

Cited by 4 publications

References 65 publications

Modified third‐order sliding mode control with adaptive gains for a multiphase PMSG wind turbine under double‐phase open fault

Modified third‐order sliding mode control with adaptive gains for a multiphase PMSG wind turbine under double‐phase open fault

A Novel Approach of Nonlinear Control in Photovoltaic/Wind/Energy Storage System With Event‐Triggered DC Link Voltage Control in DC Microgrid

A New Third-Order Continuous Sliding Mode Speed and DC-Link Voltage Controllers for a PMSG-based Wind Turbine with Energy Storage System

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