International Journal of Electrical Power System and Technology

In this Paper, a smart microgrid system's battery operation and performance were tracked using a battery charging system based on the internet of things (IoT). Due to the shifting global geography of electrical distribution and consumption, energy storage systems (ESS) are among the electrical power systems with the fastest rising market share. Traditional monitoring, detection, and optimization techniques for battery modules have drawbacks, such as a challenge balancing charging speed and battery capacity consumption. These conventional difficulties are overcome by a battery- charging system, which also improves the efficiency of managing battery modules. Real-time monitoring services with an Industry 4.0 inclination is made possible by the integration of developments and new technologies. The system's efficiency depends on the precise measurement of important variables, as well as on the battery storage system's appropriate operation and diagnostics. It has been found that a small number of research have combined the literature on various digital technologies for battery-charging systems to provide their reviews in the prior literature. However, inadequate battery storage system monitoring and safety measures can result in serious problems such battery overcharging, over discharging, overheating, unbalanced cells, thermal runaway, and fire dangers. The exact monitoring, charging-discharging control, heat management, battery safety, and protection all play critical roles in improving battery performance and addressing these issues.

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