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Flotation separation of lithium–ion battery electrodes predicted by a long short-term memory network using data from physicochemical kinetic simulations and experiments

Authors
Gomez-Flores, AllanPark, HyunsuHong, GilsangNam, HyojeongGomez-Flores, JuanKang, SeungminHeyes, Graeme W.Leal Filho, Laurindo de S.Kim, HyunjungLee, Jung MiLee, Junseop
Issue Date
Nov-2024
Publisher
ELSEVIER
Keywords
Lithium-ion battery; Direct recycling; Froth flotation; Deep learning
Citation
JOURNAL OF INDUSTRIAL INFORMATION INTEGRATION, v.42, pp 1 - 16
Pages
16
Indexed
SCIE
SCOPUS
Journal Title
JOURNAL OF INDUSTRIAL INFORMATION INTEGRATION
Volume
42
Start Page
1
End Page
16
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/211223
DOI
10.1016/j.jii.2024.100697
ISSN
2467-964X
2452-414X
Abstract
Anode and cathode active materials from spent lithium–ion batteries may be recovered and potentially used in new batteries to promote recycling and resource circulation. Froth flotation was applied to pristine active materials and the black mass obtained from pretreated spent batteries. Flotation kinetics was simulated with the use of computational fluid dynamics and surface chemistry. Bubble surface coverage and entrainment in the flotation kinetics model were selected and optimized by systematic fitting to experimental data. Entrainment influences the recovery and grade of the active materials. The optimized flotation kinetics model was used for generating additional data that, along with the fitted data, were used to train a deep learning neural network. The trained network was validated using anode–cathode and black mass flotation experiments, and its predictions showed a maximum residual error of 0.18 ± 0.11 recovery. The simulation framework was developed into a desktop application that predicts the flotation behavior of active materials. It provides information for estimating results following operational and physicochemical changes and for optimizing flotation processes. Finally, recovered anode active materials from black mass were selected for coin cell tests. The coulombic efficiency of these coin cells was initially lower (86.8 %) than that of cells made with pristine graphite particles (98.4 %).
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Kim, Hyunjung
COLLEGE OF ENGINEERING (DEPARTMENT OF EARTH RESOURCES AND ENVIRONMENTAL ENGINEERING)
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