Journal of VLSI Design and its Advancement (e-ISSN:3048-6424)

This paper proposes a decentralized methodology for distinguishing proof and characterization of shortcomings in transmission lines which involves the unique way of behaving of the generators in the power framework. After order of shortcoming, the area of the issue in the transmission line is determined. In the proposed strategy, power framework is separated into various security zones (PZ), every security zone has a generator whose pick up in speed (GIM) is checked thoroughly. With the assistance of GIM, Succession Voltage Extents at transports and responsive power move through the transmission lines the defective transmission line will be distinguished and the shortcoming is arranged. When the shortcoming is characterized with the assistance of arrangement voltages and flows at the either finishes of the transmission line issue area is determined. The issue area calculation utilized in the paper doesn't need the information on line boundaries which makes it better over the other existing calculations. The proposed strategy is tried on Western Framework Organizing Chamber 9 transport framework utilizing power world test system and PSCAD. The experimental outcome shows that the proposed technique is profoundly compelling for Wide Region Back-up Assurance of transmission lines.

Horwitz S.H., & Phakdke A.G. (2006). Third Zone Revisited. IEEE Trans Power Del., 21(1), 23-29.

Liu, Z., Chen, Z., Sun, H., & Hu, Y. (2014). Multiagent system-based wide-area protection and control scheme against cascading events. IEEE Transactions on Power Delivery, 30(4), 1651-1662.

Li, Z., Yin, X., Zhang, Z., & He, Z. (2013). Wide-area protection fault identification algorithm based on multi-information fusion. IEEE Transactions on Power Delivery, 28(3), 1348-1355.

NERC, A. (2004). 14, 2003 Blackout: NERC actions to prevent and mitigate the impacts of future cascading blackouts. North American Electric Reliability Council, Princeton, NJ, 10.

Phanendra Babu, N.V., Suresh Babu,P. & Siva Sarma, D.V.S.S. A wide- area prospective on power system protection: A state-of-art. In 2015 International Conference on Energy, Power and Environment: Towards Sustainable Growth (ICEPE), pp. 1-6. IEEE.

Eissa, M. M., Masoud, M. E., & Elanwar, M. M. M. (2009). A novel back up wide area protection technique for power transmission grids using phasor measurement unit. IEEE Transactions on Power Delivery, 25(1), 270-278.

Nayak, P. K., Pradhan, A. K., & Bajpai, P. (2014). Wide-area measurement-based backup protection for power network with series compensation. IEEE Transactions on Power Delivery, 29(4), 1970-1977.

Jena, M. K., Samantaray, S. R., & Panigrahi, B. K. (2015). A new wide- area backup protection scheme for series-compensated transmission system. IEEE Systems Journal, 11(3), 1877-1887.

Mirhosseini, S. S., & Akhbari, M. (2016). Wide area backup protection algorithm for transmission lines based on fault component complex power. International Journal of Electrical Power & Energy Systems, 83, 1-6.

Bhui, P., & Senroy, N. (2016). Real- time prediction and control of transient stability using transient energy function. IEEE Transactions on Power Systems, 32(2), 923-934.