1
Department of Electrical and Electronics, Panimalar Engineering College
(ponkumar21@gmail.com)
2
Department of Electrical and Electronics, Panimalar Engineering College
(rarvind01@gmail.com)
3
Department of Electrical and Electronics, Panimalar Engineering College
(harshadmohamed25@gmail.com)
4
Department of Electrical and Electronics, Panimalar Engineering College
(karthikrishnawork@gmail.com)
5
Department of Electrical and Electronics, Panimalar Engineering College
(itslokesh02@gmail.com)
6
Department of Electrical and Electronics, Panimalar Engineering College
(arvindpratheep@gmail.com)
7
Department of Electrical and Electronics, Panimalar Engineering College
(mmkeee2019@gmail.com)
8
Department of Electrical and Electronics, Panimalar Engineering College
(dharanibalakrish20@gmail.com)
Abstract :
When the primary power source fails, a backup power system is employed to provide electricity. This system is critical since any operation requires an uninterruptible power source. Batteries and generators that run on diesel, propane, or gasoline are currently used as backup systems. Power system blackouts occur on a frequent basis all around the world, indicating that the structure of power system protection needs to be enhanced. The existing precautions in the event of a disruption may not always allow for the localization of an emergency and subsequent self-restoration of normal operation conditions without personal input. The research direction was chosen based on the foregoing issues, presenting novel concepts and methods for preventing system blackouts and restoring normal operating conditions without the involvement of staff. Taking into account the above considerations the research direction was chosen, proposing new concept and solutions for prevention of the system blackouts and the resumption of normal operating conditions without staff participation. The inclusion of a centralized component in this structure ensures that hierarchical operating rules are followed at a higher level.
Keywords :
Islanding; Transmission power grid; self-Restoration; Versatile Electric Grid
References :
[1] M. A. M. Ariff and B. C. Pal, “Adaptive Protection and Control in the Power System for Wide-Area Blackout
Prevention,” IEEE Transactions on Power Delivery, vol. 31, no. 4, pp. 1815–1825, Aug. 2016, doi:
10.1109/TPWRD.2016.2518080.
[2] J. Barkans and D. Zalostiba, “New concept and solutions for prevention of power system blackouts,” in IET
Conference Publications, 2010, vol. 2010, no. 558 CP. doi: 10.1049/cp.2010.0312.
[3] D. Žalostība, “Short-term splitting of a power system with its self-restoration as blackout prevention H2020
RealValue (Realising Value from Electricity Markets with Local Smart Electric Thermal Storage Technology)
View project RealValue View project,” 2007. [Online]. Available:
https://www.researchgate.net/publication/235742557
[4] Institute of Electrical and Electronics Engineers. Bangladesh Section, Bangladesh University of Engineering
and Technology. Department of Electrical and Electronic Engineering, and Institute of Electrical and
Electronics Engineers, Proceedings of ICECE 2016 : venue, ECE Building, Bangladesh University of
Engineering and Technology, Dhaka-1205.
[5] Blackout Prevention Plan – The Stability, Reliability and Security Enhancement in Thailand Power Grid.
[6] Y. v. Makarov, V. I. Reshetov, V. A. Stroev, and N. I. Voropai, “Blackout prevention in the United
States,Europe, and Russia,” in Proceedings of the IEEE, 2005, vol. 93, no. 11, pp. 1942–1954. doi:
10.1109/JPROC.2005.857486.
[7] “Fuel Cell Applications.”
[8] Improving Power Networks: How Smarter Grids and a New Generation of Electricity Can Prevent Blackouts
| Style | # |
|---|---|
| MLA | G.PonKumar, ArvindRavindran, HarshadSultanT, S.N. Karthikrishna, T.Lokeshwar, S. Arvindswamy, M. Maheshkumar, B. Dharani. "Power Backup for Failsafe Power System." Journal of Cognitive Human-Computer Interaction, Vol. 3, No. 2, 2022 ,PP. 26-35 (Doi : https://doi.org/10.54216/JCHCI.030204) |
| APA | G.PonKumar, ArvindRavindran, HarshadSultanT, S.N. Karthikrishna, T.Lokeshwar, S. Arvindswamy, M. Maheshkumar, B. Dharani. (2022). Power Backup for Failsafe Power System. Journal of Journal of Cognitive Human-Computer Interaction, 3 ( 2 ), 26-35 (Doi : https://doi.org/10.54216/JCHCI.030204) |
| Chicago | G.PonKumar, ArvindRavindran, HarshadSultanT, S.N. Karthikrishna, T.Lokeshwar, S. Arvindswamy, M. Maheshkumar, B. Dharani. "Power Backup for Failsafe Power System." Journal of Journal of Cognitive Human-Computer Interaction, 3 no. 2 (2022): 26-35 (Doi : https://doi.org/10.54216/JCHCI.030204) |
| Harvard | G.PonKumar, ArvindRavindran, HarshadSultanT, S.N. Karthikrishna, T.Lokeshwar, S. Arvindswamy, M. Maheshkumar, B. Dharani. (2022). Power Backup for Failsafe Power System. Journal of Journal of Cognitive Human-Computer Interaction, 3 ( 2 ), 26-35 (Doi : https://doi.org/10.54216/JCHCI.030204) |
| Vancouver | G.PonKumar, ArvindRavindran, HarshadSultanT, S.N. Karthikrishna, T.Lokeshwar, S. Arvindswamy, M. Maheshkumar, B. Dharani. Power Backup for Failsafe Power System. Journal of Journal of Cognitive Human-Computer Interaction, (2022); 3 ( 2 ): 26-35 (Doi : https://doi.org/10.54216/JCHCI.030204) |
| IEEE | G.PonKumar, ArvindRavindran, HarshadSultanT, S.N. Karthikrishna, T.Lokeshwar, S. Arvindswamy, M. Maheshkumar, B. Dharani, Power Backup for Failsafe Power System, Journal of Journal of Cognitive Human-Computer Interaction, Vol. 3 , No. 2 , (2022) : 26-35 (Doi : https://doi.org/10.54216/JCHCI.030204) |