Transient Stability Enhancement of DFIG based Wind Generator by Switching Frequency Control Strategy with Parallel Resonance Fault Current Limiter

Transient Stability Enhancement of DFIG based Wind Generator by Switching Frequency Control Strategy with Parallel Resonance Fault Current Limiter

M. R. Islam

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M. R. I. Sheikh

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α Rajshahi University of Engineering and Technology

Transient Stability Enhancement of DFIG based Wind Generator by Switching Frequency Control Strategy with Parallel Resonance Fault Current Limiter

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Abstract

Doubly fed induction generator (DFIG) based wind turbine generation system is generally sensitive to the grid faults as its stator windings are directly connected to the grid. As the wind power penetration to the grid increases day by day, a complete shutdown of a large wind farm is not supported and continuity of power supply during grid faults according to the grid codes is very important. So, it is essential to improve the transient stability of DFIG based wind generation system. This paper investigates the impact of increasing the switching frequency of power converters of DFIG during fault conditions, and this switching frequency control (SFC) strategy is conjugated with parallel resonance fault current limiter (PRFCL) to enhance the fault ride through (FRT) of DFIG.

References

32 Cites in Article

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Funding

No external funding was declared for this work.

Conflict of Interest

The authors declare no conflict of interest.

Ethical Approval

No ethics committee approval was required for this article type.

Data Availability

Not applicable for this article.

How to Cite This Article

M. R. Islam. 2018. \u201cTransient Stability Enhancement of DFIG based Wind Generator by Switching Frequency Control Strategy with Parallel Resonance Fault Current Limiter\u201d. Global Journal of Research in Engineering - F: Electrical & Electronic GJRE-F Volume 18 (GJRE Volume 18 Issue F1): .

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GJRE Volume 18 Issue F1
Pg. 39- 48

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Journal Specifications

Crossref Journal DOI 10.17406/gjre

Print ISSN 0975-5861

e-ISSN 2249-4596

Keywords

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Classification

GJRE-F Classification: FOR Code: 290901p

Submission ReceivedDecember 6, 2017
Peer Review Double Blind
Handling Editor
Accepted January 3, 2018
Published January 15, 2018

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v1.2

Issue date

March 19, 2018

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Article Matrices

Total Score: 102

Country: Bangladesh

Subject: Global Journal of Research in Engineering - F: Electrical & Electronic

Authors: M. R. Islam, M. R. I. Sheikh (PhD/Dr. count: 0)

View Count (all-time): 214

Total Views (Real + Logic): 3133

Total Downloads (simulated): 1590

Publish Date: 2018 03, Mon

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Total Views: 3133

Total Downloads: 1590

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