Modern Analysis of Power Flow and Network Stability of Transmission Lines for Nuclear Power Dispatch
International Journal of Science, Technology and Society
Volume 7, Issue 1, January 2019, Pages: 21-32
Received: Jan. 18, 2019; Accepted: Mar. 2, 2019; Published: May 17, 2019
Views 517      Downloads 131
Swamynathan Kudiyarasan, Department of Atomic Energy, Fast Breeder Reactor, Bharatiya Nabhikiya Vidyut Nigam Limited, Kalpakkam, India
Poundraj Sivakumar, Department of Atomic Energy, Fast Breeder Reactor, Bharatiya Nabhikiya Vidyut Nigam Limited, Kalpakkam, India
Article Tools
Follow on us
This article presents an general approach to improve the power system planning, load flow pattern and stability of transmission lines using modern analysis concept. The objective is to categorize and characterize the existing system reliability concerns inherited from the adopted deterministic criteria, so that power utilities can accordingly adjust their reliability criteria to manage with real-life system uncertainties and hence to improve the overall system reliability. In the past many wide spread blackouts had occurred in interconnected power systems. Therefore it is necessary to ensure that grid should be operated economically and reliably. Contingency analysis is a well-known function in modern power system management. The aim of this analysis is to give the operator information about the static security, power flow pattern and stability. In general an outage largest capacity of one transmission line or transformer may lead to disturb the vital parameters in other lines. Modern analysis is used to calculate the violation on the network and improvement. Nuclear power plant is a base unit and best way to dispatch the power to the grid with minimum disturbance. This paper also shows the network stability, power flow management for 500MW Nuclear power plant transmission lines and connected to southern region network of India.
Power Flow, Machine Angle, Stability Analysis, Transfer Function, Transmission Grid, Fault Analysis, Distribution Network
To cite this article
Swamynathan Kudiyarasan, Poundraj Sivakumar, Modern Analysis of Power Flow and Network Stability of Transmission Lines for Nuclear Power Dispatch, International Journal of Science, Technology and Society. Vol. 7, No. 1, 2019, pp. 21-32. doi: 10.11648/j.ijsts.20190701.14
Copyright © 2019 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License ( which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Rafael Espejo, Sara Lumbreras, Andres Ramos,” Analysis of transmission-power-grid topology and scalability the European case study”, Journal of Physica A 509 (2018) 383–395,
J. C. Castro-Galeano, W. J. Cabra-Sarmiento, and J. F. Ortiz-Portilla, “Fault and load flows analysis of electricity transmission and distribution system in Casanare (Colombia),” Journal of Rev. Fac. Ing., vol. 26 (44), pp. 9-21, Ene. 2017.
Tofael Ahmeda, S. Mekhilefa, Rakibuzzaman Shahb, N. Mithulananthanc,” Investigation into transmission options for cross-border power trading in ASEAN power grid “, Journal of Energy Policy 108 (2017) 91–101 .
N Christl, R Hedig R Johnson, P Krause, A Montoya,“Power System Studies And Modelling For The Kayenta 230 kV Substation Advanced Series Compensation”, Journal of Siemen Land Western Area Power Administration USA pp. 33-37.
Y. Shi, H. D. Tuan, P. Apkarian, A. V. Savkin,“Global optimal power flow over large-scale power transmission Networks”, Journal of Systems and Control Letters 118 (2018) 16–21.
E. Cinieri, Senior Member, IEEE and A. Carrus, F. M. Gatta,“Avoiding System Collapses By Centralized Control of Power Flows Through The Interconnections Between Two Transmission Systems”.
B. Kawkabani, Member, IEEE, Y. Pannatier, J.-J. Simond, Member, IEEE,“Modeling and Transient Simulation of Unified Power Flow Controllers (UPFC) in Power System Studies”, Journal of IEEE PowerTech 2007, pp. 333-338.
Yang Feng, Daniel Tylavsky,“A Holomorphic embedding approach for finding the Type-1 power-flowSolutions”, Journal of IEEEElectrical Power and Energy Systems 102 (2018) 179–188.
Amadou Oury Ba, Tao Peng, and Serge Lefebvre,“Rotary Power-Flow Controller for Dynamic Performance Evaluation—Part II: RPFC Application in a Transmission Corridor”, Journal of IEEE TRANSACTIONS ON POWER DELIVERY, VOL. 24, NO. 3, JULY 2009.
M. Li, X. S. Han and M. Yang,“Study on the Transmission PerformanceIndex of the Complex Power Grid”.
A. V. Naresh Babu and S. Sivanagaraju,“Mathematical Modelling, Analysis and Effects of Interline Power Flow Controller (IPFC) Parameters in Power Flow Studies”.
Masoud GhiafehDavoudi, Amir Bashian, JafarEbadi,“Effects of Unsymmetrical Power Transmission System on the Voltage Balance and Power Flow Capacity of the Lines”, Journal of International Electro Technical Commission, 978-1-4577-1829-8/12/$26.00 ©2012 IEEE.
O. H. Abdalla, A. Al-Busaidi, H. Al-Hadi, H. Al-Riyami, A. Al-Nadabi, K. Karoui and A. Szekut,“Dynamic Assessment of Voltage and Reactive PowerControl in Oman Transmission System”, IEEE 8th International Power Engineering and Optimization Conference (PEOCO2014), Langkawi, The Jewel of Kedah, Malaysia. 24-25 March 2014.
Antriksh Songh, Thomos Frei, Ndaona Chokani, Reza S. Abhari, “Impact of unplanned power flows in interconnected transmission systems-Cse study of Central Eastern European region”, Energy Policy 91 (2016) pp. 287-303.
Wijarn WANGDEE,“Deterministic-based power grid planning enhancement using system well-being analysis”, J. Mod. Power Syst. Clean Energy (2018) 6(3):438–448.
Veenavati Jagadishprasad mishra, Manisha D. Khardenvis,“Contigency Analysis of Power System”, International Confrence on Emerging Frontiers in Technology for Rural Area (EFITRA) 2012.
“Manaual on Transmission Planning Criteria”, Central Electricity Authority, NewdelhiIndia, 2013.
Science Publishing Group
1 Rockefeller Plaza,
10th and 11th Floors,
New York, NY 10020
Tel: (001)347-983-5186