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An innovative approach for the optimal sizing of mini-grids in rural areas integrating the demand, the supply, and the grid

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  • Abada, Ibrahim
  • Othmani, Mehdi
  • Tatry, Léa

Abstract

On the path to universal electricity access, the most significant challenge lies in the electrification of remote rural villages where connection to the national grid is a durable but prohibitively expensive solution. With decreasing costs of renewable technologies, autonomous mini-grids combined with solar home systems constitute today an economically affordable and robust electrification option. In this paper, we elaborate a novel methodology that automatically designs and estimates the cost of the optimal mini-grid to install in a village, that requires only some geographical information with a delimitation of its roofs. In a first step, we use machine-learning algorithms to predict the demand of each building. In a second step, we develop a mathematical optimization approach to best design the mini-grid where generation and storage assets as well as the reticulation of the grid are jointly optimized. Our methodology has many advantages: first, by automating the full process, the calculation time of the electrification cost is drastically reduced by many orders of magnitude and the methodology can easily be deployed to any village/region. Second, our approach can reduce investment costs by more than 20% when compared to existing benchmarks. Finally, it can help agencies to efficiently assess the electrification costs of many regions and support them in the energy access planning.

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  • Abada, Ibrahim & Othmani, Mehdi & Tatry, Léa, 2021. "An innovative approach for the optimal sizing of mini-grids in rural areas integrating the demand, the supply, and the grid," Renewable and Sustainable Energy Reviews, Elsevier, vol. 146(C).
    • Handle: RePEc:eee:rensus:v:146:y:2021:i:c:s1364032121004056
    DOI: 10.1016/j.rser.2021.111117
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