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Main Authors: Made, Riko I, Lin, Jing, Zhang, Jintao, Zhang, Yu, Moh, Lionel C. H., Liu, Zhaolin, Ding, Ning, Chiam, Sing Yang, Khoo, Edwin, Yin, Xuesong, Zheng, Guangyuan Wesley
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2310.03750
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author Made, Riko I
Lin, Jing
Zhang, Jintao
Zhang, Yu
Moh, Lionel C. H.
Liu, Zhaolin
Ding, Ning
Chiam, Sing Yang
Khoo, Edwin
Yin, Xuesong
Zheng, Guangyuan Wesley
author_facet Made, Riko I
Lin, Jing
Zhang, Jintao
Zhang, Yu
Moh, Lionel C. H.
Liu, Zhaolin
Ding, Ning
Chiam, Sing Yang
Khoo, Edwin
Yin, Xuesong
Zheng, Guangyuan Wesley
contents Battery health assessment and recuperation play a crucial role in the utilization of second-life Li-ion batteries. However, due to ambiguous aging mechanisms and lack of correlations between the recovery effects and operational states, it is challenging to accurately estimate battery health and devise a clear strategy for cell rejuvenation. This paper presents aging and reconditioning experiments of 62 commercial high-energy type lithium iron phosphate (LFP) cells, which supplement existing datasets of high-power LFP cells. The relatively large-scale data allow us to use machine learning models to predict cycle life and identify important indicators of recoverable capacity. Considering cell-to-cell inconsistencies, an average test error of $16.84\% \pm 1.87\%$ (mean absolute percentage error) for cycle life prediction is achieved by gradient boosting regressor given information from the first 80 cycles. In addition, it is found that some of the recoverable lost capacity is attributed to the lateral lithium non-uniformity within the electrodes. An equivalent circuit model is built and experimentally validated to demonstrate how such non-uniformity can be accumulated, and how it can give rise to recoverable capacity loss. SHapley Additive exPlanations (SHAP) analysis also reveals that battery operation history significantly affects the capacity recovery.
format Preprint
id arxiv_https___arxiv_org_abs_2310_03750
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Health diagnosis and recuperation of aged Li-ion batteries with data analytics and equivalent circuit modeling
Made, Riko I
Lin, Jing
Zhang, Jintao
Zhang, Yu
Moh, Lionel C. H.
Liu, Zhaolin
Ding, Ning
Chiam, Sing Yang
Khoo, Edwin
Yin, Xuesong
Zheng, Guangyuan Wesley
Signal Processing
Materials Science
Machine Learning
Applied Physics
Battery health assessment and recuperation play a crucial role in the utilization of second-life Li-ion batteries. However, due to ambiguous aging mechanisms and lack of correlations between the recovery effects and operational states, it is challenging to accurately estimate battery health and devise a clear strategy for cell rejuvenation. This paper presents aging and reconditioning experiments of 62 commercial high-energy type lithium iron phosphate (LFP) cells, which supplement existing datasets of high-power LFP cells. The relatively large-scale data allow us to use machine learning models to predict cycle life and identify important indicators of recoverable capacity. Considering cell-to-cell inconsistencies, an average test error of $16.84\% \pm 1.87\%$ (mean absolute percentage error) for cycle life prediction is achieved by gradient boosting regressor given information from the first 80 cycles. In addition, it is found that some of the recoverable lost capacity is attributed to the lateral lithium non-uniformity within the electrodes. An equivalent circuit model is built and experimentally validated to demonstrate how such non-uniformity can be accumulated, and how it can give rise to recoverable capacity loss. SHapley Additive exPlanations (SHAP) analysis also reveals that battery operation history significantly affects the capacity recovery.
title Health diagnosis and recuperation of aged Li-ion batteries with data analytics and equivalent circuit modeling
topic Signal Processing
Materials Science
Machine Learning
Applied Physics
url https://arxiv.org/abs/2310.03750