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Electrode design optimization of lithium secondary batteries to enhance adhesion and deformation capabilities

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  • Jeong, Dongho
  • Lee, Jongsoo

Abstract

Safety, performance and lifetime of LSB (lithium secondary batteries) are affected by the adhesion of the active material to the electrode substance, and to the electrode deformation and the spring back limit in the electrode manufacturing process. This study explores the optimization process using decision tree analysis, an ANN (artificial neural network), and a multi-objective genetic algorithm. In the electrode design optimization, the objectives are to maximize the adhesion and to minimize the electrode deformation subjected to the allowable limit on the spring-back. Experimental data for use in design analysis and optimization is obtained via a measurement test. The decision tree analysis is first performed to extract major, effective parameters sensitive to adhesion force, electrode deformation and spring-back. The ANN-based approximate meta-models are then established for function approximations. The ANN-based causality analysis is further explored to determine dominant design variables for each of three design requirements for the optimization. A multi-objective optimization is finally conducted using ANN-based approximate meta-models. An optimized solution obtained from the numerical optimization process is compared with experimental data to verify the actual performance of the LSB in terms of physical and electro-chemical properties.

Suggested Citation

  • Jeong, Dongho & Lee, Jongsoo, 2014. "Electrode design optimization of lithium secondary batteries to enhance adhesion and deformation capabilities," Energy, Elsevier, vol. 75(C), pages 525-533.
    • Handle: RePEc:eee:energy:v:75:y:2014:i:c:p:525-533
    DOI: 10.1016/j.energy.2014.08.013
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    References listed on IDEAS

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    1. Zhang, Xiongwen & Kong, Xin & Li, Guojun & Li, Jun, 2014. "Thermodynamic assessment of active cooling/heating methods for lithium-ion batteries of electric vehicles in extreme conditions," Energy, Elsevier, vol. 64(C), pages 1092-1101.
    2. Pei, Lei & Zhu, Chunbo & Wang, Tiansi & Lu, Rengui & Chan, C.C., 2014. "Online peak power prediction based on a parameter and state estimator for lithium-ion batteries in electric vehicles," Energy, Elsevier, vol. 66(C), pages 766-778.
    3. Fathabadi, Hassan, 2014. "High thermal performance lithium-ion battery pack including hybrid active–passive thermal management system for using in hybrid/electric vehicles," Energy, Elsevier, vol. 70(C), pages 529-538.
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    Cited by:

    1. Eddahech, Akram & Briat, Olivier & Vinassa, Jean-Michel, 2015. "Performance comparison of four lithium–ion battery technologies under calendar aging," Energy, Elsevier, vol. 84(C), pages 542-550.
    2. Li, Jianwei & Gee, Anthony M. & Zhang, Min & Yuan, Weijia, 2015. "Analysis of battery lifetime extension in a SMES-battery hybrid energy storage system using a novel battery lifetime model," Energy, Elsevier, vol. 86(C), pages 175-185.
    3. Kou, Huaqin & Luo, Wenhua & Huang, Zhiyong & Sang, Ge & Meng, Daqiao & Zhang, Guanghui & Chen, Changan & Luo, Deli & Hu, Changwen, 2015. "Fabrication and experimental validation of a full-scale depleted uranium bed with thin double-layered annulus configuration for hydrogen isotopes recovery and delivery," Energy, Elsevier, vol. 90(P1), pages 588-594.
    4. Heidarian, Alireza & Cheung, Sherman C.P. & Ojha, Ruchika & Rosengarten, Gary, 2022. "Effects of current collector shape and configuration on charge percolation and electric conductivity of slurry electrodes for electrochemical systems," Energy, Elsevier, vol. 239(PD).

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