Optimizing battery discharge and charge strategies for enhanced Microgrid performance

https://doi.org/10.55214/2576-8484.v10i2.11976

Authors

This study aims to enhance the technical, economic, and environmental performance of hybrid microgrids (MGs) through optimal battery charging and discharging decisions. A simulation-based design integrating photovoltaic generation, battery energy storage, and diesel backup was used to evaluate multiple control strategies under identical operating conditions. A multi-objective optimization model based on the NSGA-II algorithm minimized total lifecycle cost and carbon emissions while ensuring operational resilience. The findings revealed that optimized scheduling is highly effective in enhancing renewable use, stabilizing battery state-of-charge, and virtually eliminating the need for diesel generators, resulting in over 90% cost reduction and minimal emission penalties. The optimized system showed improved net load profiles, longer battery life, and greater robustness compared to non-optimized operation. The study concludes that a battery-centric, intelligent control, and component-sizing approach is superior to renewable oversizing for the sustainability of MGs. Practically, the results show that innovative energy management can enable resilient, low-carbon, and cost-effective MG operations without increasing renewable capacity.

How to Cite

Almihat, M. G. M., & Munda, J. L. (2026). Optimizing battery discharge and charge strategies for enhanced Microgrid performance. Edelweiss Applied Science and Technology, 10(2), 20–43. https://doi.org/10.55214/2576-8484.v10i2.11976
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Issue

Vol. 10 No. 2 (2026)

Section

Articles

Published

2026-02-02

Keywords

Battery energy storage, Charge–discharge optimization, Energy management systems, Microgrids, Renewable energy integration, System resilience.