Abstract
Although the literature extensively covers the development of battery chargers control strategies, a comparison of these strategies remains a literary gap. The inherent conditions (i.e., State of Health and State of Charge) of each unit in the Battery Energy Storage Systems directly influence the charger control techniques for extending battery lifetime, which makes modular battery chargers an appealing topology for this analysis. This work groups charger control strategies presented in the literature into two: Adapted SoC strategies, directly linked to the field of overstress management, and SoH strategies, which are directly linked to the field of wear-out management. The methodology for comparing the control strategies encompasses battery lifetime, charger, and photovoltaic plant models. Three distinct cases were simulated using real measure data from a solar power plant and a battery model provided by MathWorks®. The results evidence that the Capacity Fade and Energy Throughput strongly depend on the strategy. The controller action evidences the previous statement, as the strategies have different goals that are related to each field. Furthermore, this work analyses the effect of the estimation process in the action of the controller.
Highlights
Transiting to a non-fossil energy matrix is essential to mitigate the effects that are related to global warming [1]
Battery banks without proper active charge control lead to deviations in the temperature, current, voltage, and State of Charge (SoC) of the units
Simulations in MatLab/Simulink R environment were performed to assess three possible Battery Energy Storage Systems (BESS) conditions: a new formed battery bank (Case 1), a midlife battery bank (Case 2), and a midlife battery bank in which one battery consisted of a different technology and without previous forming (Case 3)
Summary
Transiting to a non-fossil energy matrix is essential to mitigate the effects that are related to global warming [1]. The main efforts to reduce CO2 emissions are related to the introduction of renewable intermittent energy sources and the expansion of the electrification of energy systems. Energy storage is key in reducing the costs of renewable energy grids operating with intermittent energy sources. Among different options of energy storage, batteries have important advantages, such as high technological maturity, modularity, facilitated adaptability, and relatively low maintenance in up-to-date energy systems. Another energy storage option that is gaining prominence is fuel-cells, but these devices present technical challenges, such as those described in [3]
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