Implementation and Validation of Hybrid Control for a DFIG Wind Turbine Using an FPGA Controller Board

Taoussi, Mohammed; Bossoufi, Badre; Bouderbala, Manale; Motahhir, Saad; Alkhammash, Eman H.; Masud, Mehedi; Zinelaabidine, Nada; Karim, Mohammed

doi:10.3390/electronics10243154

Cited by 15 publications

(13 citation statements)

References 20 publications

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“…Gholipour 73 With bus voltage control 0.42 Without bus voltage control 0.61 Taoussi et al 74 Hybrid control 0.94 Bouderbala et al 75 Predictive control 0.49 Benchmark strategy [8][9][10] the use of proposed ISC controller, which we can say that the proposed strategy can be relied upon in controlling electric generators.…”

Section: Nosratabadi Andmentioning

confidence: 99%

A new integral-synergetic controller for direct reactive and active powers control of a dual-rotor wind system

Benbouhenni,

Bizon,

Thounthong

et al. 2023

Measurement and Control

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This paper proposes a new integral-synergetic controller for direct reactive and active powers control (DARPC) for a grid-connected doubly-fed induction generators (DFIGs) in dual-rotor wind power generation applications. The proposed DARPC strategy employs integral-synergetic control (ISC) to regulate the reactive and active powers of the DFIG-based variable speed dual-rotor wind turbine systems. The proposed ISC technique is the contribution of this work, where this strategy is a development of synergetic control and simplicity and robustness are the most prominent features. The main advantages of the proposed ISC-DARPC technique are ease of implement, good dynamic response, simple structure, and constant switching frequency operation. The Matlab software is used to validate the design of the ISC-DARPC technique, and the obtained results are compared with traditional DARPC. In addition, the ISC-DARPC technique is able to fully minimize ripples in both torque and active power during grid voltage imbalance or parametric changes on the DFIG.

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Section: Nosratabadi Andmentioning

confidence: 99%

A new integral-synergetic controller for direct reactive and active powers control of a dual-rotor wind system

Benbouhenni,

Bizon,

Thounthong

et al. 2023

Measurement and Control

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“…The mathematical-model of the DFIG in the (𝑑 − 𝑞) frame is presented in the following equations. The stator and the rotor voltages are given by the following equations [19][20][21]:…”

Section: Modelling Of Dfigmentioning

confidence: 99%

Archives of Electrical Engineering

2022

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The paper proposes a new robust fuzzy gain adaptation of the sliding mode (SMC) power control strategy for the wind energy conversion system (WECS), based on a doubly fed induction generator (DFIG), to maximize the power extracted from the wind turbine (WT). The sliding mode controller can deal with any wind speed, ingrained nonlinearities in the system, external disturbances and model uncertainties, yet the chattering phenomenon that characterizes classical SMC can be destructive. This problem is suitably lessened by adopting adaptive fuzzy-SMC. For this proposed approach, the adaptive switching gains are adjusted by a supervisory fuzzy logic system, so the chattering impact is avoided. Moreover, the vector control of the DFIG as well as the presented one have been used to achieve the control of reactive and active power of the WECS to make the wind turbine adaptable to diverse constraints. Several numerical simulations are performed to assess the performance

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“…Indeed, the first maintains the turbine's distortion at speeds over its nominal value [9], whereas the MPPT extracts the maximum energy [10]. The wind operation zone can be separated into four zones (Figure 2).…”

Section: Introduction 1backgroundmentioning

confidence: 99%

Real-Time Power Control of Doubly Fed Induction Generator Using Dspace Hardware

et al. 2023

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Numerous studies have been undertaken to evaluate wind energy systems’ active and reactive power control, the energy produced, and their its link to distribution networks. This research makes a novel contribution to the discipline in this setting. The novelty of this work aims to design a new wind emulator and design a power control approach for a doubly fed induction generator (DFIG)-based wind system. A description of the system was provided first. Secondly, the control strategy was described in detail. Then, it was applied to both converters (machine and grid sides). Three stages were used to evaluate the control solution: (1) a MATLAB/Simulink simulation to validate the reference’s persistence (for both real and step wind speeds) and the system’s robustness, (2) implementation in real-time on a dSPACE-DS1104 board linked to an experimental laboratory bench, and (3) overlapped comparison experimental and simulated data to conduct a thorough quantitative and qualitative analysis using the root-mean-square error measures. The simulation and experimental findings demonstrate that the suggested model is valid and presents an excellent correlation between experimental and simulated results regarding wind speed variation.

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Implementation and Validation of Hybrid Control for a DFIG Wind Turbine Using an FPGA Controller Board

Cited by 15 publications

References 20 publications

A new integral-synergetic controller for direct reactive and active powers control of a dual-rotor wind system

A new integral-synergetic controller for direct reactive and active powers control of a dual-rotor wind system

Archives of Electrical Engineering

Real-Time Power Control of Doubly Fed Induction Generator Using Dspace Hardware

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