Techniques for Ensuring Fault Ride-Through Capability of Grid Connected DFIG-Based Wind Turbine Systems: A Review

Shuaibu, Musayyibi; Abubakar, Adamu Saidu; Shehu, Auwal

doi:10.4314/njtd.v18i1.6

Cited by 6 publications

(6 citation statements)

References 32 publications

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“…According to Shuaibu, M. et al (2021) [39], the electrical grid is incorporating renewable energy sources (RES) as a supplement to conventional sources and to meet the rising demand for electrical energy globally. Grid connected DFIG-based WECS are subject to network interruptions since the windings of the stator and grid are directly interconnected.…”

Section: Related Workmentioning

confidence: 99%

Control Strategies of DFIG Technology-based Variable-Speed Wind Turbines-A Review

Giri,

Mishra,

Patra

et al. 2024

IOP Conf. Ser.: Earth Environ. Sci.

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This review paper examines the advancements and limitations of wind energy technology, while concentrating on the utilization of Doubly Fed Induction Generators (DFIG) to capture maximum power in variable speed winds. The paper evaluates the efficacy of several control strategies for DFIG relying on WT (wind turbines), on the basis of their simulation results, key features, and control objectives. The paper highlights the potential areas for investigation to improvise the performance as well as efficiency of wind energy generation.

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Section: Related Workmentioning

confidence: 99%

Control Strategies of DFIG Technology-based Variable-Speed Wind Turbines-A Review

Giri,

Mishra,

Patra

et al. 2024

IOP Conf. Ser.: Earth Environ. Sci.

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“… [ 98 ] Compensating voltage swell by limiting the fault short circuit current through the application of dynamic voltage resistor (DVR)-FLC technique in ensuring to develop robust system of enhanced power quality. [ 99 ] Improving power reliability Reducing the model complexity of different DFIG-turbine systems by making use of the novel model reduction margin (MRM) as optimization strategy and the New England test system (NETS) as evaluation model; while evaluating the damping torque contribution to stability margin from the dynamic model components of these systems. [ 100 ] Employing an enhanced primary frequency response (PFR) strategy so as to reduce the pitch angle to slowly feed the active power to the grid system in improving the frequency stability of the system.…”

Section: Wecs Technologiesmentioning

confidence: 99%

“…For instance, the power quality of the grid connected DFIG system was considered to be enhanced by employing low voltage ride through (LVRT) strategy that was developed as capacitor-inductor series connection and capacitor/inductor-resistor parallel connection [ 95 ]; the impact of rotor current attenuation process on the DFIG system components and power stability was studied based on the real-time data service (RTDS) and physical controller in enabling the enhancement of power quality and power devices protection [ 96 ]. In addition, non-superconducting fault current limiter that was based on bridge-type flux coupling method [ 97 ]; external retrofit and internal control techniques [ 98 ]; and dynamic voltage resistor (DVR)-FLC technique [ 99 ] were also proposed to enhance FRT capability based on the modeling of DFIG system components. Moreover, the power reliability with DFIG system operations was reported to be improved based on the implementation of different research modeling strategies including: a novel model reduction margin (MRM) & New England test system (NETS) [ 100 ]; an enhanced primary frequency response (PFR) [ 101 ]; etc.…”

Section: Wecs Technologiesmentioning

confidence: 99%

Wind energy conversion technologies and engineering approaches to enhancing wind power generation: A review

Desalegn

Gebeyehu²,

Tamirat³

2022

Heliyon

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“…Sardar Kamil et al [13] reviewed the several control strategies for maintaining the low voltage ride through (LVRT) capability of grid-feeding converters, with their benefits and drawbacks, thereby presenting a comparative listing of various current control loops where vector control is chosen as the primary control with various rotor parameters as reference. In [14], stator flux orientation and Lyapunov theory are proposed as an LVRT solution with an enhanced control technique of stator powers exchanged between the DFIG and the grid. Geng et al developed control strategies with grid side converters (GSCs) for unsymmetrical faults in grid integrated wind systems [15,16].…”

Section: Introductionmentioning

confidence: 99%

Fuzzy-Based EV Charging Station and DVR-Fed Voltage Compensation for a DFIG-Fed Wind Energy System during Grid Faults

Uthra

Suchitra

Babu

et al. 2022

International Transactions on Electrical Energy Systems

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In recent years, it can be seen that more and more wind energy systems are integrated to focus on developing a more reliable energy system. A doubly-fed induction generator is the most employed machine in wind energy systems having the advantages of variable speed operation, improved power quality, and high energy capture. In a wind energy conversion system (WECS), the generator’s capability to remain connected during short electric faults resulting in voltage sag is known as fault ride through (FRT). Over the last few years, electric vehicles have been providing a remarkable solution for many sustainability issues such as global warming, depletion of fossil fuel reserves, and emission of greenhouse gas that needs attention to detail. A voltage compensation using Dynamic Voltage Restorer and Electric Vehicle charging station both employing a fuzzy controller is proposed in this paper for sustaining FRT capability. The variation in the stator voltage is tracked and utilized to inject the necessary shortfall of voltage in the system via DVR or EV charging station for the intensity of the created voltage sag. Vehicle-to-grid unit of the electric vehicle charging station comes into action when voltage sag intensity is 0.9 p.u. to 0.51 p.u. Value of the nominal voltage and the DVR takes over when voltage sag falls between 0.5 p.u. and 0.2 p.u. Consequently, this voltage compensation regulates the other relative parameters like DC link voltage and active power and retains them within the permissible limits during the fault.

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Techniques for Ensuring Fault Ride-Through Capability of Grid Connected DFIG-Based Wind Turbine Systems: A Review

Cited by 6 publications

References 32 publications

Control Strategies of DFIG Technology-based Variable-Speed Wind Turbines-A Review

Control Strategies of DFIG Technology-based Variable-Speed Wind Turbines-A Review

Wind energy conversion technologies and engineering approaches to enhancing wind power generation: A review

Fuzzy-Based EV Charging Station and DVR-Fed Voltage Compensation for a DFIG-Fed Wind Energy System during Grid Faults

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