Abstract
A combination of wind generator and battery storage provides a potential solution for electrification in remote areas. The intermittency issues associated with wind power can be suitably handled if battery storage is optimally integrated with it. The determination of optimal component size is a combinatorial optimization problem and must be adequately addressed in order to have reliability standards coupled with cost-effectiveness. This paper presents a reliability-based determination of component sizes for an isolated hybrid power system using wind generators as well as storage. A competent nature inspired algorithm called as Butterfly PSO has been used for optimization problem. The objective is minimization of economic parameter called as Levelized cost of energy (LCOE). Expected energy not served (EENS) has been used as the reliability constraint. A case study has been carried out for an isolated hybrid power system sited in India.
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Paliwal, P. (2022). Reliability-Based Optimal Sizing for an Isolated Wind–Battery Hybrid Power System Using Butterfly PSO. In: Bansal, R.C., Agarwal, A., Jadoun, V.K. (eds) Advances in Energy Technology. Lecture Notes in Electrical Engineering, vol 766. Springer, Singapore. https://doi.org/10.1007/978-981-16-1476-7_16
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