Research Article
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Year 2020, , 25 - 30, 08.06.2020
https://doi.org/10.31593/ijeat.680639

Abstract

References

  • R. Chedid and S. Rahman, “Unit sizing and control of hybrid wind-solar power systems”, IEEE Transactions on Energy Conversion, 12(1), 79-85, 1997.
  • T. Senjyu, D. Hayashi, N. Urasaki and T. Funabashi, “Optimum Configuration for Renewable Generating Systems in Residence Using Genetic Algorithm”, IEEE Transactions on Energy Conversion, 21(2), 459-466, 2006.
  • T. Niknam, A. Kavousifard, S. Tabatabaei and J. Aghaei, “Optimal operation management of fuel cell/wind/photovoltaic power sources connected to distribution networks”, Journal of Power Sources, 196(20), 8881-8896, 2011.
  • S. Kumaravel, S. Ashok and P. Balamurugan, “Techno-economic feasibility study of biomass based hybrid renewable energy system for microgrid application“, International Conference on Green Technologies (ICGT), 2012.
  • M. Bortolini, M. Gamberi and A. Graziani, “Technical and economic design of photovoltaic and battery energy storage system”, Energy Conversion and Management, 86, 81-92, 2014.
  • González, J.-R. Riba and A. Rius, “Optimal Sizing of a Hybrid Grid-Connected Photovoltaic–Wind–Biomass Power System”, Sustainability, 7(9), 12787-12806, 2015.
  • M. A. Mohamed, A. M. Eltamaly and A. I. Alolah, “Swarm intelligence-based optimization of grid-dependent hybrid renewable energy systems”, Renewable and Sustainable Energy Reviews, 77, 515-524, 2017.
  • O. Krishan and S. Suhag, “Techno-economic analysis of a hybrid renewable energy system for an energy poor rural community”, Journal of Energy Storage, 23, 305–319, 2019.
  • Tajeddin and E. Roohi, “Designing a reliable wind farm through hybridization with biomass energy”, Applied Thermal Engineering, 154, 171–179, 2019.
  • N. Yang, J. Pouget, T. Letrouvé, C. Jecu and L. Joseph-Auguste, “Techno-economic design methodology of hybrid energy systems connected to electrical grid: An application of hybrid railway power substation”, Mathematics and Computers in Simulation, 158, 107–119, 2019.
  • P.A. Hohne, K. Kusakana, B.P. Numbi, “Optimal energy management and economic analysis of a grid-connected hybrid solar water heating system: A case of Bloemfontein, South Africa”, Sustainable Energy Technologies and Assessments, 31, 273–291, 2019.
  • P. Bento, H. Nunes, J. Pombo, M.d.R. Calado and S. Mariano, “Daily Operation Optimization of a Hybrid Energy System Considering a Short-Term Electricity Price Forecast Scheme”, Energies, 12, 924-948, 2019.
  • A.F. Touré, S.A. Addouche, F. Danioko, B. Diourté and A. El Mhamedi, “Hybrid Systems Optimization: Application to Hybrid Systems Photovoltaic Connected to Grid. A Mali Case Study”, Sustainability, 11, 2356-2375, 2019.
  • D.A. Konneh, H.O.R. Howlader, R. Shigenobu, T. Senjyu, S. Chakraborty and N. Krishna, “A multi-criteria decision maker for grid-connected hybrid renewable energy systems selection using multi-objective particle swarm optimization”, Sustainability 11, 1188–1223, 2019.

Optimization of a grid connected hybrid energy system

Year 2020, , 25 - 30, 08.06.2020
https://doi.org/10.31593/ijeat.680639

Abstract

Nowadays, energy policy makers in Turkey are discussing about transition to regional energy pricing policy due to the illegal usage rates in some regions in the country. A possible transition to regional pricing policy needs a detailed analysis on development of regional energy networks. By developing such networks, outer-dependency of energy can be reduced in regions and energy costs can reduce by using energy generation potential from renewable resources within regional networks. Moreover, the existing energy grid can be considered as a backup option to satisfy shortened demand after generation from renewable resources. In other words, grid-connected hybrid energy systems can be a promising solution to satisfy energy demand at a lower cost. Hybrid energy systems are discovered as a beneficial way to provide sustainable energy supply in regions with renewable energy potential. On the other hand, these kind of energy systems requires an analytic investigation in terms of design and operation, because of the existence of different energy resources. So, optimization of system design and operation decisions are extremely important. In this paper, optimization of a hybrid energy network is considered and a linear programming model to optimize operation decisions in a hybrid energy network for a town is proposed. The proposed model is solved on a numerical example with 10 demand points and 2 generation plants. An operation strategy for the numerical example is obtained after solution with a commercial LP solver. This model can be used a decision support tool for policy makers in development of energy policies.

References

  • R. Chedid and S. Rahman, “Unit sizing and control of hybrid wind-solar power systems”, IEEE Transactions on Energy Conversion, 12(1), 79-85, 1997.
  • T. Senjyu, D. Hayashi, N. Urasaki and T. Funabashi, “Optimum Configuration for Renewable Generating Systems in Residence Using Genetic Algorithm”, IEEE Transactions on Energy Conversion, 21(2), 459-466, 2006.
  • T. Niknam, A. Kavousifard, S. Tabatabaei and J. Aghaei, “Optimal operation management of fuel cell/wind/photovoltaic power sources connected to distribution networks”, Journal of Power Sources, 196(20), 8881-8896, 2011.
  • S. Kumaravel, S. Ashok and P. Balamurugan, “Techno-economic feasibility study of biomass based hybrid renewable energy system for microgrid application“, International Conference on Green Technologies (ICGT), 2012.
  • M. Bortolini, M. Gamberi and A. Graziani, “Technical and economic design of photovoltaic and battery energy storage system”, Energy Conversion and Management, 86, 81-92, 2014.
  • González, J.-R. Riba and A. Rius, “Optimal Sizing of a Hybrid Grid-Connected Photovoltaic–Wind–Biomass Power System”, Sustainability, 7(9), 12787-12806, 2015.
  • M. A. Mohamed, A. M. Eltamaly and A. I. Alolah, “Swarm intelligence-based optimization of grid-dependent hybrid renewable energy systems”, Renewable and Sustainable Energy Reviews, 77, 515-524, 2017.
  • O. Krishan and S. Suhag, “Techno-economic analysis of a hybrid renewable energy system for an energy poor rural community”, Journal of Energy Storage, 23, 305–319, 2019.
  • Tajeddin and E. Roohi, “Designing a reliable wind farm through hybridization with biomass energy”, Applied Thermal Engineering, 154, 171–179, 2019.
  • N. Yang, J. Pouget, T. Letrouvé, C. Jecu and L. Joseph-Auguste, “Techno-economic design methodology of hybrid energy systems connected to electrical grid: An application of hybrid railway power substation”, Mathematics and Computers in Simulation, 158, 107–119, 2019.
  • P.A. Hohne, K. Kusakana, B.P. Numbi, “Optimal energy management and economic analysis of a grid-connected hybrid solar water heating system: A case of Bloemfontein, South Africa”, Sustainable Energy Technologies and Assessments, 31, 273–291, 2019.
  • P. Bento, H. Nunes, J. Pombo, M.d.R. Calado and S. Mariano, “Daily Operation Optimization of a Hybrid Energy System Considering a Short-Term Electricity Price Forecast Scheme”, Energies, 12, 924-948, 2019.
  • A.F. Touré, S.A. Addouche, F. Danioko, B. Diourté and A. El Mhamedi, “Hybrid Systems Optimization: Application to Hybrid Systems Photovoltaic Connected to Grid. A Mali Case Study”, Sustainability, 11, 2356-2375, 2019.
  • D.A. Konneh, H.O.R. Howlader, R. Shigenobu, T. Senjyu, S. Chakraborty and N. Krishna, “A multi-criteria decision maker for grid-connected hybrid renewable energy systems selection using multi-objective particle swarm optimization”, Sustainability 11, 1188–1223, 2019.
There are 14 citations in total.

Details

Primary Language English
Subjects Industrial Engineering
Journal Section Research Article
Authors

Ahmet Aktas 0000-0002-4394-121X

Mehmet Kabak 0000-0002-8576-5349

Publication Date June 8, 2020
Submission Date January 27, 2020
Acceptance Date April 23, 2020
Published in Issue Year 2020

Cite

APA Aktas, A., & Kabak, M. (2020). Optimization of a grid connected hybrid energy system. International Journal of Energy Applications and Technologies, 7(2), 25-30. https://doi.org/10.31593/ijeat.680639
AMA Aktas A, Kabak M. Optimization of a grid connected hybrid energy system. IJEAT. June 2020;7(2):25-30. doi:10.31593/ijeat.680639
Chicago Aktas, Ahmet, and Mehmet Kabak. “Optimization of a Grid Connected Hybrid Energy System”. International Journal of Energy Applications and Technologies 7, no. 2 (June 2020): 25-30. https://doi.org/10.31593/ijeat.680639.
EndNote Aktas A, Kabak M (June 1, 2020) Optimization of a grid connected hybrid energy system. International Journal of Energy Applications and Technologies 7 2 25–30.
IEEE A. Aktas and M. Kabak, “Optimization of a grid connected hybrid energy system”, IJEAT, vol. 7, no. 2, pp. 25–30, 2020, doi: 10.31593/ijeat.680639.
ISNAD Aktas, Ahmet - Kabak, Mehmet. “Optimization of a Grid Connected Hybrid Energy System”. International Journal of Energy Applications and Technologies 7/2 (June 2020), 25-30. https://doi.org/10.31593/ijeat.680639.
JAMA Aktas A, Kabak M. Optimization of a grid connected hybrid energy system. IJEAT. 2020;7:25–30.
MLA Aktas, Ahmet and Mehmet Kabak. “Optimization of a Grid Connected Hybrid Energy System”. International Journal of Energy Applications and Technologies, vol. 7, no. 2, 2020, pp. 25-30, doi:10.31593/ijeat.680639.
Vancouver Aktas A, Kabak M. Optimization of a grid connected hybrid energy system. IJEAT. 2020;7(2):25-30.