Title :
Multi-objective design of PV-wind-batteries hybrid systems by minimizing the annualized cost system and the loss of power supply probability (LPSP)
Author :
Bilal, B. Ould ; Sambou, V. ; Ndiaye, P.A. ; Kebe, C.M.F. ; Ndongo, M.
Author_Institution :
Centre Int. de Formation et de Rech. en Energie Solaire (C.I.F.R.E.S)/ESP/UCAD, Dakar, Senegal
Abstract :
This paper deals with a methodology of sizing hybrid systems solar/wind/battery optimized by minimizing the annualized cost system (ACS) and the loss of power supply probability (LPSP) using multi-objective genetic algorithm. The developed methodology was applied using the hourly solar, temperature and the wind speed data collected for one year on the site of Potou located in the northwestern coast of Senegal. The annual average hourly load profile of a typical remote village located in the northwestern coast of Senegal which energy is of 94 kWh/day has been used. The obtained results show that the cost of the optimal configuration strongly depends on the loss of power supply probability (LPSP). For example, the cost of the optimal configuration decreases by 25 % when the loss of power supply probability (LPSP) grows to 1% from 0%.
Keywords :
battery storage plants; genetic algorithms; hybrid power systems; photovoltaic power systems; power generation economics; probability; solar power stations; wind power plants; ACS; LPSP; PV-wind-batteries hybrid systems; annualized cost system; hybrid system solar-wind-battery sizing; multiobjective design; multiobjective genetic algorithm; power supply probability loss; wind speed data; Batteries; Hybrid power systems; Inverters; Power supplies; Regulators; Wind speed; Wind turbines; Hybrid system; Minimizing; genetic algorithm; optimization;
Conference_Titel :
Industrial Technology (ICIT), 2013 IEEE International Conference on
Conference_Location :
Cape Town
Print_ISBN :
978-1-4673-4567-5
Electronic_ISBN :
978-1-4673-4568-2
DOI :
10.1109/ICIT.2013.6505784
