(Publisher of Peer Reviewed Open Access Journals)

International Journal of Advanced Technology and Engineering Exploration (IJATEE)

ISSN (Print):2394-5443    ISSN (Online):2394-7454
Volume-8 Issue-76 March-2021
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Paper Title : Arduino-based battery monitoring system with state of charge and remaining useful time estimation
Author Name : Melbern Rose C. Maltezo, August C. Thio-ac, Anna May C. Castillo, Leandro E. Gattu, Carmine Ella A. Hernandez, Jonarld John C. Labuan, Leonard F. Navales, Erickson C. Sopeña, Nilo M. Arago, Edgar A. Galido, Gilfred Allen M. Madrigal, Cherry G. Pascion and Lean Karlo S. Tolentino
Abstract :

This paper presents a battery management system for lead-acid battery banks used in e-vehicle. It is incorporated with a diagnostic, measurement, and monitoring system for improving Lead-acid battery performance up to its efficiency and conservation. This matter calls the need for research on traction batteries as an insatiate demand exists for smaller vehicles with lightweight and portable equipment. It is extensive that batteries are strictly assessed and diagnosed before having them rented or exchanged for their condition to be highly maintained. The measurement of the battery’s State-of-Charge and State-of-Health is derived from its load voltage, no-load voltage, load current, and temperature during experimentation. The estimation of State-of-Charge, State-of-Health, Discharge Rate, and Remaining Useful Life are then derived by utilizing the concept of correlation and regression from the yielded real-time parameters recorded to the SD card module. This study paves the approach for the comprehensive and continuous progress of battery identification, monitoring, and diagnosis that is a thorough advancement in the E-Vehicle industry.

Keywords : Battery management system, Lead-acid, Arduino-based management system, Electric vehicle, State of charge, State of health, Remaining Useful time, Discharge rate.
Cite this article : Maltezo MR, Thio-ac AC, Castillo AC, Gattu LE, Hernandez CE, Labuan JJ, Navales LF, Sopeña EC, Arago NM, Galido EA, Madrigal GA, Pascion CG, Tolentino LK. Arduino-based battery monitoring system with state of charge and remaining useful time estimation. International Journal of Advanced Technology and Engineering Exploration. 2021; 8(76):432-444. DOI:10.19101/IJATEE.2021.874023.
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