Abstract
Nowadays, the development concept of renewable energy conversion facilities is adopted by the majority of countries as a property to be promoted urgently in order to provide global and sustainable solutions to environmental challenges and to cope with the undeniable depletion of fossil energy resources. Indeed, renewable energies (solar, wind, etc.) are a promising alternative for achieving an energy transition and sustainable economic development. In view of the report on the accelerated depletion of fossil resources due to the ever increasing energy needs and the challenges of environmental preservation of carbon dioxide emissions, the use of renewable resources for the production of electricity is a promising alternative. However, solar and wind resources are of intermittent types because the wind turbine output power varies with the wind speed at different conditions and the solar energy also varies with the hourly, daily and seasonal variation of solar irradiation, we propose in this work, behavioural study and analysis of an hybrid generation system combining solar and wind energy connected to the grid with a battery (energy storage) to ensure that the system performs under different climatic conditions.
The objective of this work is to ensure the best performances of the proposed hybrid configuration under different possible operating scenarios. Energy management between of renewable energy sources (PV-arrays, wind generator and energy storage), component the hybrid generation system and considered in order to meet the sustained load demands during the varying natural conditions.
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Lakhdara, A., Bahi, T., Moussaoui, A.K. (2021). Control and Management Solar-Wind-Storage Hybrid System. In: Hatti, M. (eds) Artificial Intelligence and Renewables Towards an Energy Transition. ICAIRES 2020. Lecture Notes in Networks and Systems, vol 174. Springer, Cham. https://doi.org/10.1007/978-3-030-63846-7_1
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DOI: https://doi.org/10.1007/978-3-030-63846-7_1
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