Optimal Sizing and Location of Solar Capacity in an Electrical Network Using Lightning Search Algorithm

The transition from centralized power grids to microgrids (MGs) has facilitated the increased integration of renewable energy sources (RES) to the power systems. However, the operational cost in MGs is highly dependent on planning decisions. Therefore, the optimal sizing and placement of RES will of...

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Bibliographic Details
Published in:Electric power components and systems 2019-09, Vol.47 (14-15), p.1247-1260
Main Authors: Muqbel, Ammar, Elsayed, Abubakr H., Abido, Mohamed A., Mantawy, Abdel-Aal, Al-Awami, Ali T., El-Hawary, Mohamed
Format: Article
Language:English
Subjects:
Algorithms
Cost control
differential evolution algorithm
Electric power grids
Electric power systems
Electrical networks
Evolutionary algorithms
Evolutionary computation
Lightning
lightning search algorithm
Linearity
Operating costs
optimal sizing and placement
Optimization
Optimization techniques
Placement
Power loss
Renewable energy sources
Search algorithms
Sizing
solar capacity
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Summary:The transition from centralized power grids to microgrids (MGs) has facilitated the increased integration of renewable energy sources (RES) to the power systems. However, the operational cost in MGs is highly dependent on planning decisions. Therefore, the optimal sizing and placement of RES will offer significant savings in operational costs and reduce power losses in the system. This study proposes a new technique for optimal sizing and placement of solar capacity in the electrical network to minimize the operational cost of conventional generators and real power losses. Due to the complexity and non-linearity associated with the problem, a new natural inspired optimization technique called lightning search algorithm (LSA) is developed to find the optimal solution. To assess LSA, differential evolution algorithm is also used to solve the same problem and a comparison is conducted to prove the superiority of LSA in reducing computation time. The optimization problem is applied to IEEE 14- and 30-bus systems with 24-hr load and solar profile. The obtained results verify the effectiveness of the proposed LSA approach to obtain the optimal sizing and placement of RES and reduce operational cost and power losses.
ISSN:1532-5008
1532-5016
DOI:10.1080/15325008.2019.1659456