Grid integration of renewables: challenges and solutions
Authors
-
,IN
K. V. Vidyanandan -
,INBalkrishn Kamath
DOI:
https://doi.org/10.18311/ijprvd/2021/29662Keywords:
distributed generation, energy storage, power quality, solar PV, wind energyAbstract
Exponential growth in the energy demand on account of rising population and economic growth, increasing apprehensions of energy security coupled with climate change and global warming concerns are some of the major drivers for pushing the renewable energy (RE) to the top of the energy portfolio. Among various renewable energy resources, wind and solar PV systems are experiencing rapid growth since 2010. By the end of 2016, the world total capacity of wind power generation was 487 GW and that of solar PV was 303 GW, aggregating to a penetration level of 4.0% and 1.5% respectively. Global renewable energy penetration till December 2016, excluding conventional hydro share (of 16.6%) was only around 8.0%. However, many countries have set target of 30% RE based electricity generation by 2030. India has an ambitious target of achieving 175 GW of RE power by 2022, with 100 GW from solar, 60 GW from wind, 10 GW from biomass and 5 GW from small hydro. Power generation from renewables often takes place through distributed generation (DG). These units, mostly located in remote locations, are not centrally planned or dispatched, and are usually connected to distribution grids at LV or MV levels. In few cases, large capacity RE generation are also connected to transmission networks. As a result, the power generation structure is moving from the large, centralized plants to a mixed generation pool consisting of traditional large plants and many smaller DG units. Most of the RE generators have electrical characteristics that are different from the synchronous machines. Since a large group of DG technologies use power electronics converters for grid connectivity, they introduce many technical issues related to the operation, control and protection of the power system, impacting generators, transmission system and consumer devices. This paper presents some of the technical issues and challenges that need to be addressed for the effective grid integration of RE based power generators so that eventually our reliance on polluting and expensive fossil based hydrocarbon driven power generation can be reduced substantially.
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Accepted 2022-02-24
Published 2022-02-24
References
BP Statistical Review of World Energy, June 2017.
Renewables 2017 Global Status Report, REN-21.
Lalor G., Mullane A. and Malley M.O., (2005): Frequency control and wind turbine technologies, IEEE Trans. Power Sys., vol. 20, No. 4, pp. 1905-1913, November.
Morren J., de Haan S.W.H., and Kling W.L., (2006): Wind turbines emulating inertia and supporting primary frequency control, IEEE Trans. Power Sys., vol. 21, No. 1, pp. 433-434, February.
Ackermann T., (2005): Wind power in power systems, Wiley.
IEEE Std. 519-2014, IEEE Recommended Practice and Requirements for Harmonic Control in Electric Power Systems.
Kundur P. (1994): Power system stability and control, McGraw Hill.
Gevorgian V. and Booth S., (2013): Review of PREPA Technical Requirements for Interconnecting Wind and Solar Generation , NREL Technical Report, NREL/TP- 5D00-57089, November.
Jenkins N., et al, (2000): Embedded Generation, IEE Power and Engineering Series 31, Institution of Electrical Engineers, London.
Freris L. and Infield David, (2008): Renewable Energy in Power Systems, John Wiley.
Lundberg S., (2000): “Electrical limiting factors for wind energy installations”, Chalmers University of Technology, Göteborg, Sweden.
IEEE Std. 1159-2009, IEEE Recommended Practice for Monitoring Electric Power Quality.
Mohseni M., M. Masoum A.S., and Islam S.M., (2011): Low and high voltage ride-through of DFIG wind turbines using hybrid current controlled converters, Electric Power Systems Research, pp.1456–1465, vol. 81, no.7, July.
Walling R., Ellis A., and Gonzalez S., (2014): Implementation of Voltage and Frequency Ride- Through Requirements in Distributed Energy Resources Interconnection Standards, Sandia National Laboratories Technical Report 2014-3122, California, April.
Large Scale Grid Integration of Renewable Energy Sources - Way Forward, Central Electricity Authority, India, November. 2013.
Vidyanandan K. V. and Senroy, N. (2012): Issues in the grid frequency regulation with increased penetration of wind energy systems, IEEE Students Conference on Engineering and Systems (SCES 2012), pp.1-6, MNNIT, Allahabad, U. P., India. 16-18, March.
