Abstract
Lithium-ion batteries find a wide range of applications in UPS, mobiles, electric vehicle, and in commonly used electronic items. Lithium-ion batteries are preferred because of their advantages of having low self-discharge, low maintenance, and also high energy density. Even though lithium-ion batteries have many advantages, it gets heated up when it is continuously used. So, monitoring of various factors such as charging/discharging cycle, temperature, input/output voltage and current using a battery management system is the main objective of this proposed system. Measurement of these parameters helps to identify the health of the battery and predict the life of the battery. When the temperature is increasing beyond normal, then the cooling system is activated so that the battery remains at normal temperature and works efficiently. The measured values of the parameters will be displayed in a liquid crystal display, and it will also be transferred to the cloud by ESP module through Arduino programming. The research work is experimentally verified for a 12 V, 2000mAh lithium-ion battery with 2A constant DC load conditions.
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Madhankumar, S., Dharshini, S., Vignesh, N.R., Amrutha, P., Dhanaselvam, J. (2022). Cloud Computing-Based Li-Ion Battery-BMS Design for Constant DC Load Applications. In: Ranganathan, G., Fernando, X., Shi, F., El Allioui, Y. (eds) Soft Computing for Security Applications . Advances in Intelligent Systems and Computing, vol 1397. Springer, Singapore. https://doi.org/10.1007/978-981-16-5301-8_22
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DOI: https://doi.org/10.1007/978-981-16-5301-8_22
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