TY - JOUR
T1 - Analyzing the Behavior of Li-B Electrothermal Voltage and Capacity Loss under Varying Temperatures and Discharge rates
AU - Arsalan, M.
AU - Farzaneh, H.
N1 - Publisher Copyright:
© 2023, Kyushu University. All rights reserved.
PY - 2023
Y1 - 2023
N2 - Lithium batteries are preferred for electric vehicles due to their high energy density, power output, rechargeability, efficiency, durability, and positive environmental impact. To enhance energy density of Li-B, electrochemical models are carefully designed after analyzing at changing charging and discharging behaviors to improve the efficiency. However, the complex structure arising from numerous physical parameters hampers better analysis of key battery parameters. This paper presents an electrothermal model in which batter’s dynamic electrical parameters are simulated using Impedance-based Chen and Mora electrical equivalent circuit while thermal characteristics are simulated using the Bernard’s Heat equation. Besides, accurate battery voltage is calculated using voltage compensation offset. Moreover, using the proposed model, the study investigates the impact of different ambient temperatures and charge/discharge rates on battery voltage. Additionally, a semi-empirical model is also proposed here to assesses the lifespan of Li-B by accounting two of the major Capacity Losses i.e., Calendar Loss and Cycle Loss. Similarly, the proposed battery-life-prediction model is also used to analyze behavior of battery parameters under varying temperatures and discharge rates.
AB - Lithium batteries are preferred for electric vehicles due to their high energy density, power output, rechargeability, efficiency, durability, and positive environmental impact. To enhance energy density of Li-B, electrochemical models are carefully designed after analyzing at changing charging and discharging behaviors to improve the efficiency. However, the complex structure arising from numerous physical parameters hampers better analysis of key battery parameters. This paper presents an electrothermal model in which batter’s dynamic electrical parameters are simulated using Impedance-based Chen and Mora electrical equivalent circuit while thermal characteristics are simulated using the Bernard’s Heat equation. Besides, accurate battery voltage is calculated using voltage compensation offset. Moreover, using the proposed model, the study investigates the impact of different ambient temperatures and charge/discharge rates on battery voltage. Additionally, a semi-empirical model is also proposed here to assesses the lifespan of Li-B by accounting two of the major Capacity Losses i.e., Calendar Loss and Cycle Loss. Similarly, the proposed battery-life-prediction model is also used to analyze behavior of battery parameters under varying temperatures and discharge rates.
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U2 - 10.5109/7157982
DO - 10.5109/7157982
M3 - Conference article
AN - SCOPUS:85184310719
SN - 2434-1436
VL - 9
SP - 261
EP - 266
JO - International Exchange and Innovation Conference on Engineering and Sciences
JF - International Exchange and Innovation Conference on Engineering and Sciences
T2 - 9th International Exchange and Innovation Conference on Engineering and Sciences, IEICES 2023
Y2 - 19 October 2023 through 20 October 2023
ER -