Journal Press India^®

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Real-time modelling of the IEEE 13-node test feeder is accomplished with the help of a microgrid implementation. As a consequence, a quantified real-time platform is produced. The IEEE standard provides the basis for this paradigm. Solar photovoltaic panels and wind turbine electricity can both be used in microgrids. Both of these are non-conventional sources of energy. Studying how environmental friendly sources can be integrated into the micro-grid and how the micro-grid and system reliability can be evaluated simultaneously is a main goal of this study work. Secondly, we want to learn how to include ecologically friendly sources and analysis into our daily practises. Radial feeders have an imbalance due to renewable energy sources being connected at the appropriate bus. Solar panels and wind turbines are two examples of these green energy options. A microgrid is a self-contained network linked to the main grid through the distribution system. It is possible to run a micro-grid without relying on the main grid, despite its link. In a microgrid scenario, the modelling software Matlab/Simulink is being used to simulate an imbalanced three-phase power supply. Microgrids are equipped with batteries for power storage. Findings show that a number of distinct time-shifting buses have considerably improved their voltage and current profiles.

Keywords

Solar Photovoltaic; Radial Feeders; Distribution System; Non-Conventional Energy Resources; Distribution Energy System

1. H. E. Brown, S. Suryanarayanan, G. T. Heydt, “ Some characteristics of emerging stributdiion systems considering the Smart Grid Initiative ,” The Electricity Journal, v. 23, no. 5, June 2010, pp.64-75.
2. T. Ackermann and V. Knyazkin, “Interaction between distributed generation and the distribution network: Operation aspects”, Second Int. Symp. Distributed Generations: Power System Market Aspects, Stockholm, Sweden, 2002.
3. Jatin jangra and shelly vadhera,”load flow analysis for three phase unbalanced distribution feeder using matlab”, ICCT, 2017.
4. S. Suryanarayanan, M. Steurer, S. Woodruff, R. Meeker, “ Research perspectives on high fidelity modeling, simulation, and hardware-in-the-loop for electric grid infrastructure hardening,” in Proc. 2007 IEEE Power Engineering Society (PES) General Meeting , 4 pp., Jul2007.
5. T. Ackermann and V. Knyazkin, “Interaction between distributed generation and the distribution network: Operation aspects”, Second Int. Symp. Distributed Generations: Power System Market Aspects, Stockholm, Sweden, 2002.
6. C. Abbey, F. Katiraei, C. Brothers, “Integration of distributed generation and windenergy in Canada”, Invitedpaper IEEE Power EngineeringSociety General Meetingand Conference, Montreal, Canada, June 18-22,2006.
7. W. Kersting, “Radial distribution test feeders,” Power Systems, IEEE Transactions on, vol. 6, no. 3, pp. 975–985, Aug 1991
8. P.A Upadhyay and S.k Joshi”, Optimal Summation of Natural Power Distributed Resources in Grid Connected Micro Grid”, ICIT, 2019.
9. N. Hatziargyriou, H. Asano, R. Iravani, C. Marnay, “Micro-grids- Anover view of ongoing research, development and demonstra- tion projects”, IEEE Power and Energy Magazine, pp. 78-94, July/August2007.
10. Dr. K. Ravi chandrudu, M.Manasa, Mr. P.Yohan Babu, G.V.P. Anjaneyulu “ Design of Micro- grid System Based on Renewable Power Generation Units”, International Journalof Scientific and Research Publications, Volume 3, Issue 8, August 2013 ISSN2250-3153.
11. N. Pogaku, M. Prodanovic, T. C. Green, “Modeling, analysis and testing of autonomous operation of an inverter-based microgrid,” IEEE Trans. Power Electron., vol. 22, no. 2, pp. 613 625, Mar.2007.
12. Akshay K. Rathore, “Hybrid Micro-grid (μG) Based Residential Utility Interfaced Smart Energy System: Applications for Green Data Centers and Commercial Buildings”, 7th IEEE Conference on Industrial Electronicsand Applications, Singapore, July 2012, pp. 2063- 2068.
13. H. Yan, N. Lv, F. Zhuo, H. Yi and Z. Wang, "Energy Management of Household microgrid with Multiple Energy Resources for Rural Area," 2019 10th International Conference on Power Electronics and ECCE Asia (ICPE 2019 - ECCE Asia), Busan, Korea (South), 2019, pp. 1 -6.
14. Roshen Tariq and Ahmad Hamdi,” Solar cell system simulation using Matlab-Simulink”, Kurdistan Journal for Applied Research kjar.spu.edu.iq Volume 2, Issue 1, June 2017.
15. Kumar, Y., Mishra, R.N. and Anwar, A., 2020, February. Enhancement of Small Signal Stability of SMIB System using PSS and TCSC. In 2020 International Conference on Power Electronics & IoT Applications in Renewable Energy and its Control (PARC) (pp. 102-106). IEEE.
16. Dr. K. Ravi chandrudu, M.Manasa, Mr. P.Yohan Babu, G.V.P. Anjaneyulu “ Design of Micro- grid System Based on Renewable Power Generation Units”, International Journalof Scientific and Research Publications, Volume 3, Issue 8, August 2013 ISSN2250-3153.
17. J.N. Paquin, J. Moyen, G. Dumur, V. Lapointe, “ Real-Time and Off-Line Simulation of a Detailed WindFarm Model Connected to a Multi-Bus Network”, IEEE Canada Electrical Power Conference 2007, Montreal, Oct. 25-26,2007.
18. J. Arai, K. Iba, T. Funabashi, Y. Nakanishi, K. Koyanagi, and R. Yokoyama, “ Power elec- tronicsand itsapplications to renewable energy in Japan,” IEEE Circuits Syst., vol. 8, no. 3, pp. 52-66, Sep.2008
19. Kumar, Y. and Gupta, H., 2022, April. Load Flow Analysis of Distribution generator using the unsynchronized Measurement. In 2022 Second International Conference on Advances in Electrical, Computing, Communication and Sustainable Technologies (ICAECT) (pp. 1-5). IEEE.
20. A. Paudel and G. H. Beng, "A Hierarchical Peer-to-Peer Energy Trading in Community Microgrid Distribution Systems," 2018 IEEE Power & Energy Society General Meeting (PESGM), Portland, OR, 2018, pp. 1-5, doi: 10.1109/PESGM.2018.8586168.
21. Y. Kumar, M. Pushkarna and G. Gupta, "Microgrid Implementation in Unbalanced Nature of Feeder using Conventional Technique," 2020 3rd International Conference on Intelligent Sustainable Systems (ICISS), 2020, pp. 1489-1494, doi: 10.1109/ICISS49785.2020.9316024.
22. Sharma, K., & Shukla, M. (2014). Molecular modeling of the mechanical behavior of carbon fiber-amine functionalized multiwall carbon nanotube/epoxy composites. New Carbon Materials, 29(2), 132–142. https://doi.org/10.1016/S1872-5805(14)60131-1