Evaluation of batteries residual energy for battery pack recycling: Proposition of stack stress-coupled-AI approach
Created by W.Langdon from
gp-bibliography.bib Revision:1.8110
- @Article{GARG:2019:JES,
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author = "Akhil Garg and Li Wei and Ankit Goyal and
Xujian Cui and Liang Gao",
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title = "Evaluation of batteries residual energy for battery
pack recycling: Proposition of stack
stress-coupled-{AI} approach",
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journal = "Journal of Energy Storage",
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volume = "26",
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pages = "101001",
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year = "2019",
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ISSN = "2352-152X",
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DOI = "doi:10.1016/j.est.2019.101001",
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URL = "http://www.sciencedirect.com/science/article/pii/S2352152X1930790X",
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keywords = "genetic algorithms, genetic programming, Energy
storage, Battery pack recycling, Residual energy",
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abstract = "It is predicted that by 2025, approximately 1 million
metric tons of spent battery waste will be accumulated.
How to reasonably and effectively evaluate the residual
energy of the lithium-ion batteries embedded in
hundreds in packs used in Electric Vehicles (EVs) grows
attention in the field of battery pack recycling. The
main challenges of evaluation of the residual energy
come from the uncertainty of
thermo-mechanical-electrochemical behavior of battery.
This motivates the notion of facilitating research on
establishing a model which can detect and predict the
state of battery based on parameters enable to be
measured, such as voltage and stack stress. Thus, the
present work proposes a stack stress-coupled-artificial
intelligence approach for analyzing the residual energy
(remaining) in the batteries. Experiments are designed
and performed to verify the fundamentals. A robust
model is formulated based on artificial intelligence
approach of genetic programming. The findings in the
study can provide an optimized recycling strategy for
spent batteries by accurately predicting the state of
battery based on stack stress",
- }
Genetic Programming entries for
Akhil Garg
Li Wei
Ankit Goyal
Xujian Cui
Liang Gao
Citations