Abstract
The problems associated with the deployment of intermittent, unpredictable and uncontrollable solar photovoltaics (PV) can be feasibly solved with battery energy storage systems (BESS), particularly in terms of optimizing the available capacity, increasing reliability and reducing system losses. Consequently, the degree of importance of BESS increases in proportion to the level of PV penetration. Nevertheless, the respective high cost of BESS imposes a huge concern and the need to establish a techno-economic solution. In this paper, we investigate the system losses and power quality issues associated with the high deployment of PV in a grid network and hence formulate BESS capacity optimization and placement methodology based on a genetic algorithm. The concept of the proposed methodology has been tested and validated on a standard IEEE 33 bus system. A brief stepwise analysis is presented to demonstrate the effectiveness and robustness of the proposed methodology in reducing the incremental system losses experienced with increased PV penetration. Furthermore, based on the proposed optimization objectives, a comparative study has also been performed to quantify the impact and effectiveness of aggregated and distributed placement of BESS. The results obtained exhibit a substantial reduction in system losses, particularly in the case of distributed BESS placement.
Highlights
IntroductionNations all around the globe are progressing towards a cleaner environment. Over the years, the accumulation of several factors brought about the unprecedented requirement for renewable energy resources (RES) as a possible integration to power networks [1,2]
Today, nations all around the globe are progressing towards a cleaner environment
This study outlines the contribution of high PV penetration towards system losses in a distributed power network and its potential mitigation based on optimal placement of battery energy storage systems (BESS)
Summary
Nations all around the globe are progressing towards a cleaner environment. Over the years, the accumulation of several factors brought about the unprecedented requirement for renewable energy resources (RES) as a possible integration to power networks [1,2]. The conceptual installation of RESs as distributed energy resources (DER) in a grid network has been established to provide advantages such as independency from exhaustible/dwindling carbon-based generations, meet the ever-increasing electric power demand, eco-friendly power generation and option for load side generation that mitigates the need for grid expansion to a certain extent [3]. Most of the matured potential RES technologies such as solar (PV) and wind energy sources, possess a threat to power quality of the power network and limits their economic significance [4], due to their transient power generation characteristics that explicitly impacts the reliability and power quality of the grid [5]. The realization of smart grids has been postulated and promoted to establish and optimally operate distributed networks more effectively and economically [6].
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