Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines

The manual reaction approach to faults is exhibited in conventional grid. Manual operations are slow in many cases and resulting in big fault and power cut. Turkey has experienced it by living on March 31, 2015. The switching to smart grids is inevitable in order to minimize human errors and avoid big failures. It is a solution to turn the appropriate zones back to the island mode, especially in case of emergency load shedding due to the basic frequency. However, large power fluctuations occur in the microgrids when switching to the island mode or connecting to the grid. Therefore, In Matlab / Simulink, a microgrid is designed that can operate in island mode in accordance with the smart grid structure to minimize the damage of symmetrical and asymmetrical of high voltage lines on loads, grid and its components in this study. Also the effects of Superconducting Fault Current Limiter (SFCL) have been studied to limit power fluctuations in the microgrid when switching to island mode and exit island mode. In addition, autonomous maneuver management has been carried out on the designed high voltage line to prevent faults resulting in long term power cut.

Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines

The manual reaction approach to faults is exhibited in conventional grid. Manual operations are slow in many cases and resulting in big fault and power cut. Turkey has experienced it by living on March 31, 2015. The switching to smart grids is inevitable in order to minimize human errors and avoid big failures. It is a solution to turn the appropriate zones back to the island mode, especially in case of emergency load shedding due to the basic frequency. However, large power fluctuations occur in the microgrids when switching to the island mode or connecting to the grid. Therefore, In Matlab / Simulink, a microgrid is designed that can operate in island mode in accordance with the smart grid structure to minimize the damage of symmetrical and asymmetrical of high voltage lines on loads, grid and its components in this study. Also the effects of Superconducting Fault Current Limiter (SFCL) have been studied to limit power fluctuations in the microgrid when switching to island mode and exit island mode. In addition, autonomous maneuver management has been carried out on the designed high voltage line to prevent faults resulting in long term power cut.

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Bibtex @araştırma makalesi { politeknik681807, journal = {Politeknik Dergisi}, eissn = {2147-9429}, address = {Gazi Üniversitesi Teknoloji Fakültesi 06500 Teknikokullar - ANKARA}, publisher = {Gazi Üniversitesi}, year = {2020}, volume = {23}, number = {4}, pages = {1371 - 1377}, doi = {10.2339/politeknik.681807}, title = {Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines}, key = {cite}, author = {Üstünsoy, Furkan and Yıldız, Sadık and Yılmaz, Ercan Nurcan and Sayan, Hasan Hüseyin and Burunkaya, Mustafa and Yılmaz, Cemal and Bulut, Mithat} }
APA Üstünsoy, F. , Yıldız, S. , Yılmaz, E. N. , Sayan, H. H. , Burunkaya, M. , Yılmaz, C. & Bulut, M. (2020). Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines . Politeknik Dergisi , 23 (4) , 1371-1377 . DOI: 10.2339/politeknik.681807
MLA Üstünsoy, F. , Yıldız, S. , Yılmaz, E. N. , Sayan, H. H. , Burunkaya, M. , Yılmaz, C. , Bulut, M. "Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines" . Politeknik Dergisi 23 (2020 ): 1371-1377 <
Chicago Üstünsoy, F. , Yıldız, S. , Yılmaz, E. N. , Sayan, H. H. , Burunkaya, M. , Yılmaz, C. , Bulut, M. "Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines". Politeknik Dergisi 23 (2020 ): 1371-1377
RIS TY - JOUR T1 - Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines AU - Furkan Üstünsoy , Sadık Yıldız , Ercan Nurcan Yılmaz , Hasan Hüseyin Sayan , Mustafa Burunkaya , Cemal Yılmaz , Mithat Bulut Y1 - 2020 PY - 2020 N1 - doi: 10.2339/politeknik.681807 DO - 10.2339/politeknik.681807 T2 - Politeknik Dergisi JF - Journal JO - JOR SP - 1371 EP - 1377 VL - 23 IS - 4 SN - -2147-9429 M3 - doi: 10.2339/politeknik.681807 UR - Y2 - 2020 ER -
EndNote %0 Politeknik Dergisi Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines %A Furkan Üstünsoy , Sadık Yıldız , Ercan Nurcan Yılmaz , Hasan Hüseyin Sayan , Mustafa Burunkaya , Cemal Yılmaz , Mithat Bulut %T Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines %D 2020 %J Politeknik Dergisi %P -2147-9429 %V 23 %N 4 %R doi: 10.2339/politeknik.681807 %U 10.2339/politeknik.681807
ISNAD Üstünsoy, Furkan , Yıldız, Sadık , Yılmaz, Ercan Nurcan , Sayan, Hasan Hüseyin , Burunkaya, Mustafa , Yılmaz, Cemal , Bulut, Mithat . "Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines". Politeknik Dergisi 23 / 4 (Aralık 2020): 1371-1377 .
AMA Üstünsoy F. , Yıldız S. , Yılmaz E. N. , Sayan H. H. , Burunkaya M. , Yılmaz C. , Bulut M. Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines. Politeknik Dergisi. 2020; 23(4): 1371-1377.
Vancouver Üstünsoy F. , Yıldız S. , Yılmaz E. N. , Sayan H. H. , Burunkaya M. , Yılmaz C. , Bulut M. Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines. Politeknik Dergisi. 2020; 23(4): 1371-1377.
IEEE F. Üstünsoy , S. Yıldız , E. N. Yılmaz , H. H. Sayan , M. Burunkaya , C. Yılmaz ve M. Bulut , "Autonomous Operation of Microgrid and Minimization of Fault in Case of Failure in High-Voltage Lines", Politeknik Dergisi, c. 23, sayı. 4, ss. 1371-1377, Ara. 2020, doi:10.2339/politeknik.681807
Politeknik Dergisi
  • ISSN: 1302-0900
  • Yayın Aralığı: Yılda 4 Sayı
  • Başlangıç: 1998

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