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Multi-scale modelling of Lithium-ion batteries : from transport phenomena to the outbreak of thermal runaway
ID Katrašnik, Tomaž (Author), ID Mele, Igor (Author), ID Zelič, Klemen (Author)

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Abstract
Multi-scale and multi-domain mathematical models capable of modelling main electrochemical reactions, side reactions and heat generation can reduce the time and cost of lithium-ion battery development and deployment, since these processes decisively influence performance, durability and safety of batteries. Experimental evidences clearly indicate the importance of the interplay between electric and thermal boundary conditions, cell design and applied materials, side reactions as well as safety implications of batteries, which are not yet captured to a sufficient level by simulations models. As an answer to this challenge, the paper presents an advanced multi-scale battery modelling framework that can be seamlessly integrated into multi-domain models. The key hypothesis is that nanoscopic transport phenomena and resulting heat generation decisively influence the entire chain of mechanisms that can lead to the outbreak of the thermal runaway. This is confirmed by developing a multi-scale battery modelling framework that is based on the continuous modelling approach featuring more consistent virtual representation of the electrode topology and incorporating the coupled chain of models for heat generations and side reactions. As a result, the battery modelling framework intuitively yet insightfully elucidates the entire chain of phenomena from electric and thermal boundary conditions, over cell design and properties of applied materials to solid electrolyte interphase growth, its decomposition and subsequent side reactions at the anode, cathode and the electrolyte that lead to the thermal runaway. One of key results comprises multi-level main and side reaction driven heat transfer cross-talk between the anode and the cathode. Therefore, the presented advanced multi-scale battery modelling framework represents a contribution to the advanced virtual development of batteries thereby contributing to tailoring battery design to a specific application.

Language:English
Keywords:Li-ion battery, phase separating material, continuum model, multi-scale modelling, heat generation, thermal runaway
Work type:Article
Typology:1.01 - Original Scientific Article
Organization:FS - Faculty of Mechanical Engineering
Publication status:Published
Publication version:Version of Record
Year:2021
Number of pages:22 str.
Numbering:Vol. 236, art. 114036
PID:20.500.12556/RUL-125941 This link opens in a new window
UDC:621.31:519.8(045)
ISSN on article:0196-8904
DOI:10.1016/j.enconman.2021.114036 This link opens in a new window
COBISS.SI-ID:58992387 This link opens in a new window
Publication date in RUL:09.04.2021
Views:1439
Downloads:255
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Record is a part of a journal

Title:Energy conversion and management
Shortened title:Energy convers. manage.
Publisher:Elsevier
ISSN:0196-8904
COBISS.SI-ID:2618919 This link opens in a new window

Licences

License:CC BY-NC-ND 4.0, Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International
Link:http://creativecommons.org/licenses/by-nc-nd/4.0/
Description:The most restrictive Creative Commons license. This only allows people to download and share the work for no commercial gain and for no other purposes.

Secondary language

Language:Slovenian
Keywords:Li-ionske baterije, material s fazno separacijo, kontinuumski model, večskalno modeliranje, generacija toplote, termični pobeg

Projects

Funder:ARRS - Slovenian Research Agency
Project number:P2-0401
Name:Energetsko strojništvo

Funder:ARRS - Slovenian Research Agency
Project number:J7-8270
Name:Nova generacija elektrokemijskega baterijskega modela LiFePO4

Funder:ARRS - Slovenian Research Agency
Project number:J2-2494
Name:Napredni večskalni model NMC katodnih materialov za izboljšane sisteme za shranjevanje energije naslednje generacije

Funder:EC - European Commission
Funding programme:H2020
Project number:769506
Name:Optimization of scalaBle rEaltime modeLs and functIonal testing for e-drive ConceptS
Acronym:OBELICS

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