Evolution of the electricity networks towards Smart Grid in the Andean Region countries
DOI:
https://doi.org/10.26507/rei.v8n15.285Keywords:
Smart Grid, electrical power system, distributed energy resources, plug–in electric vehicles, advanced metering infrastructureAbstract
Nowadays, one of the main unanswered questions is related to the production and use of electricity because it is expected an increase in the cost of generation, including the Andean Countries. Reason given, this article presents an analysis of the problems that the configurations of Electric Systems of Modern Potency entail. Furthermore, some important components and the requirements that guide the evolution of the electric energy distribution system towards Smart Grid are formulated. These components give an intelligence improvement to the system (Advanced Metering Infrastructure), integrating the Information and Communication Technologies (Telecommunication Architecture Models), offering a better exploitation of the alternative energy fonts (Distributed Generation – Micro networks), a faster answer to failure, and an adaptation to the use of Electric Vehicles (Interaction between Energy Networks and Plug-in Electric Vehicles). In conclusion, all the process mentioned above will go towards the evolution of Smart Grid in the Andean Countries.
Downloads
References
Anderson, D., Zhao, C., Hauser, C., Venkatasubramanian, V., Bakken, D., & Bose, A. (2012). Intelligent Design Real-Time Simulation for Smart Grid Control and Communications Design. Power and Energy Magazine, IEEE, 10(1), 49-57.
Bouhafs, F., Mackay, M., & Merabti, M. (2012). Links to the Future: Communication Requirements and Challenges in the Smart Grid. Power and Energy Magazine, IEEE, 10(1), 24-32.
Bu, S., Yu, F., Liu, P., & Zhang, P. (2011). Distributed scheduling in smart grid communications with dynamic power demands and intermittent renewable energy resources. 1-5.
Chen, K., Yeh, P., Hsieh, H., & Chang, S. (2010). Communication infrastructure of smart grid. 1-5.
Commission, E., & others. (2006). European SmartGrids technology platform: vision and strategy for europe’s electricity networks of the future., 22040, 37.
Fan, Z., Kulkarni, P., Gormus, S., Efthymiou, C., Kalogridis, G., Sooriyabandara, M., . . . Chin, W. (2011). Smart Grid Communications: Overview of Research Challenges, Solutions, and Standardization Activities. Communications Surveys & Tutorials, IEEE(99), 1-18.
Feng, Z., & Yuexia, Z. (2011). Study on smart grid communications system based on new generation wireless technology. 1673-1678.
Galli, S., Scaglione, A., & Wang, Z. (2010). Power line communications and the smart grid. 303-308.
Gao, J., Xiao, Y., Liu, J., Liang, W., & Chen, C. (2012). A survey of communication/networking in Smart Grids. Future Generation Computer Systems, 28(2), 391-404.
Gungor, V., Sahin, D., Kocak, T., Ergut, S., Buccella, C., Cecati, C., & Hancke, G. (2011). Smart Grid Technologies: Communications Technologies and Standards. Industrial Informatics, IEEE Transactions on(99), 1-11.
IEEE Standard Communication Delivery Time Performance Requirements for Electric Power Substation Automation. ( de 2005). IEEE Standard Communication Delivery Time Performance Requirements for Electric Power Substation Automation(Print: ISBN 0-7381-4502-5 SS95283 PDF: ISBN 0-7381-4503-3 SS95283), 0_1 -24.
Ikki, S., Amin, O., & Uysal, M. (2010). Performance Analysis of Adaptive L-QAM for Opportunistic Decode-and-Forward Relaying. 1-5.
Jun-ping, S., Wan-Xing, S., Sun-an, W., & Wu, K. (2002). Substation automation high speed network communication platform based on MMS+ TCP/IP+ Ethernet. 2, 1296-1300.
Käbisch, S., Schmitt, A., Winter, M., & Heuer, J. (2010). Interconnections and communications of electric vehicles and smart grids. 161-166.
Kansal, P., & Bose, A. (2011). Smart grid communication requirements for the high voltage power system. 1-6.
Marris, E. (July de 2008). Upgrading The Grid. News Feature, 454, 570 - 573.
Niyato, D., & Wang, P. (2012). Cooperative Transmission for Meter Data Collection in Smart Grid. IEEE Communications Magazine, 50(4), 90.
Overman, T., & Sackman, R. (2010). High assurance smart grid: Smart grid control systems communications architecture. 19-24.
Patel, A., Aparicio, J., Tas, N., Loiacono, M., & Rosca, J. (2011). Assessing communications technology options for smart grid applications. 126-131.
Seo, D., Lee, H., & Perrig, A. (2011). Secure and Efficient Capability-Based Power Management in the Smart Grid. 119-126.
Shahraeini, M., Javidi, M., & Ghazizadeh, M. (2010). A new approach for classification of data transmission media in power systems. 1-7.
Tuttle, D., & Baldick, R. (2012). The Evolution of Plug-in Electric Vehicle-Grid Interactions. Smart Grid, IEEE Transactions on, 3(1), 500-505.
Xiao, Y. (2012). Communication and Networking in Smart Grids. New York: {CRC} Press.
Yang, Y., Hu, H., Xu, J., & Mao, G. (2009). Relay technologies for WiMAX and LTE-advanced mobile systems. Communications Magazine, IEEE, 47(10), 100-105.
Zhou, J., Hu, R., & Qian, Y. (2012). Scalable Distributed Communication Architectures to Support Advanced Metering Infrastructure in Smart Grid. 1-12.
Downloads
Published
How to Cite
Issue
Section
License
Total or partial reproduction of the documents published in the journal is authorized only when the source and author are cited.
| Article metrics | |
|---|---|
| Abstract views | |
| Galley vies | |
| PDF Views | |
| HTML views | |
| Other views | |
