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Electro-chemo-mechanically coupled computational modelling of structural batteries

David Carlstedt, Kenneth Runesson, Fredrik Larsson, Johanna Xu, E. Leif

2020Multifunctional Materials40 citationsDOIOpen Access PDF

Abstract

Abstract Structural batteries are multifunctional composites that combine load-bearing capacity with electro-chemical energy storage capability. The laminated architecture is considered in this paper, whereby restriction is made to a so called half-cell in order to focus on the main characteristics and provide a computational tool for future parameter studies. A thermodynamically consistent modelling approach is exploited for the relevant electro-chemo-mechanical system. We consider effects of lithium insertion in the carbon fibres, leading to insertion strains, while assuming transverse isotropy. Further, stress-assisted ionic transport is accounted for in addition to standard diffusion and migration. The relevant space-variational problems that result from time discretisation are established and evaluated in some detail. The proposed model framework is applied to a generic/idealized material representation to demonstrate its functionality and the importance of accounting for the electro-chemo-mechanical coupling effects. As a proof of concept, the numerical studies reveal that it is vital to account for two-way coupling in order to predict the multifunctional (i.e. combined electro-chemo-mechanical) performance of structural batteries.

Topics & Concepts

DiscretizationIsotropyCoupling (piping)Representation (politics)Lithium (medication)Computer scienceDiffusionMaterials scienceMechanical engineeringStructural engineeringEngineeringMathematicsPhysicsMathematical analysisThermodynamicsEndocrinologyPoliticsPolitical scienceMedicineQuantum mechanicsLawAdvanced Battery Technologies ResearchAdvanced Battery Materials and TechnologiesAdvancements in Battery Materials
Electro-chemo-mechanically coupled computational modelling of structural batteries | Litcius