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Thermal Modelling of Thermal Runaway Propagation in Lithium-Ion Battery SystemsElisabeth Irene Kolp (M.Sc.), Prof. Dr.-Ing. Andreas Jossen
Technical University of Munich, Germany
Department of Electrical and Computer Engineering
Institute for Electrical Energy Storage Technology
Petten, 8th & 9th March 2018
Agenda
2Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Method toinvestigate abusive
behaviour
Simulation model forthermal runaway
propagation (TR-P)
Mitigation strategiesof battery TR-P
Limitations of accurate modelling
of TR-P
Agenda
3Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Method toinvestigate abusive
behaviour
Simulation model forthermal runaway
propagation (TR-P)
Mitigation strategiesof battery TR-P
Limitations of accurate modelling
of TR-P
Empirical method to investigate abusive behaviour
4Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Measure heat generation rate of a nail penetrated battery inside a calorimeter
18650 NCA battery
vented gas
E_gas(0-20s) = 30 kJE_cell(0-20s) = 72 kJ
Empirical method to investigate abusive behaviour
5Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Measure trigger temperature of thermal runaway with heat-wait-seek method
Empirical method to investigate abusive behaviour
6Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Measure trigger temperature of thermal runaway: compare to literature
[Golubkov A., Royal Society of Chemistry, Vol. 5, 2015]
Tested cell: 18650 NCA 3.35 Ah
Agenda
7Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Method toinvestigate abusive
behaviour
Simulation model forthermal runaway
propagation (TR-P)
Mitigation strategiesof battery TR-P
Limitations of accurate modelling
of TR-P
Conductive thermal model for TR propagation
8Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
FEM-model of lithium-ionbattery module
Lithium-ion batterymodule (12s1p)
Material properties
Meshing
Geometry
Boundary conditions
Conductive thermal model for TR propagation
9Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
FEM-model of lithium-ionbattery module
Material properties
Meshing
Geometry
Boundary conditions
ARC/Calorimeter:• Heat generation rate• Heat capacity• Trigger temperature of thermal
runaway
Custom Hot Disk / Literature:• Heat capacity• Thermal conductivity (anisotrop)
Simulation: 12s1p modulenail penetration of a single cell
10Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
t = 10 s t = 110 s
t = 180 s t = 240 s
°C
°C
nail
141 180
module case
hole
bottom
Experiment: 12s1p modulenail penetration of a single cell
11Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
nail
141 180
module case
hole
bottom
dashed line: simulationsolid line: experiment
Experiment: 12s1p modulenail penetration of a single cell
12Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Experiment: 12s1p modulenail penetration of a single cell
13Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Results:• Conductive thermal model approach cannot
describe the TR-P of experiment
• Heat release of gas and direction of gas flow have a strong influence on TR-P
Implementing gas flow / venting necessary
CFD model
1st CFD model approach for TR propagation
14Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Model assumptions:
• 2D, k-ε model for turbulence
• vfluid,inlet = 215 m/s [Coman P.T., JoP 307 (2016)]
• Tfluid,inlet = measured data
• Vent position extracted from module experiment
• Gas = similar specs like hydrogen
Neglected:
• Cell connector → heat transfer via solid bodies
• Heat generation of nail penetrated cell
t0
t0+0.5 s
Results:• t > 0 ; Tfluid >> Tinitial
• t > 0 ; Toutlet >> Tinitial
• t > 0 ; Tcells >> Tinitial
• Direction of gas flow
Problem:
• 3D CFD simulation is time consuming
• Uncertain input parameters
• Experiment (nail penetration)not suitable
1st CFD model approach for TR propagation
15Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
t0
t0+0.5 s
Average cell temperature
Agenda
16Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Method toinvestigate abusive
behaviour
Simulation model forthermal runaway
propagation (TR-P)
Mitigation strategiesof battery TR-P
Limitations of accurate modelling
of TR-P
General:
• Temperature dependent material properties for > 100 °C not available
• 3D-CFD simulation is time consuming
Understanding and describing venting by a model needs accurate data on
• Vent size and vent position
• Heat release, mass rate, velocity of vented gas
Limitations of accurate of modelling TR-P
17Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
venting model[Leung J.C., AiChE, Vol. 38, No. 5, 1992]
Missing information makes it hard to simulate TR-P withsimplified thermal models, especially if venting gas occurs
Agenda
18Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Method toinvestigate abusive
behaviour
Simulation model forthermal runaway
propagation (TR-P)
Mitigation strategiesof battery TR-P
Limitations of accurate modelling
of TR-P
Experimental results of a 2s1p module for nailpenetration of a single cell
19Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
• In the beginning rapid temperature increase ofcell connector due to opened berst
→ Isolation prevents TR-P
Nail penetrated cell
cellconnector
Isolation
Ideas:• Increase trigger temperature of thermal runaway (by changing separator)
PE, PP/PE/PP, PE-based with ceramic coating
• Use of electrical fuses → reduce released electric energy during internal shortcircuite.g. Tesla uses wire bonding which act as fuses too
• Increase heat dissipation of battery moduleby lower ambient temperature or increased thermal capacity e.g. phase-change-material
• Additional thermal resistance between cells
• Protect neighbor cells of venting gas (define predetermined breaking pointson cell)
Mitigation strategies of battery TR-P
20Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
[Tesla Motors Inc., 2010, patent US8241772 B2]
• Venting gas during TR can have a strong influence on TR-P inside a battery module
• Conductive thermal models cannot represent TR-P if venting occurs inside a (half-)closed battery module
• Approach to implement heat transfer by gas looks promising and shows qualitativ the TR-P behavior
More information on physical properties and behavior of venting gas during TR are necessary
Standardised abuse testing regarding TR-P by venting gas is required
Summary
21Safer Li-Ion Batteries by Preventing Thermal Propagation? | Petten 2018 | Elisabeth I. Kolp (TUM)
Elisabeth I. Kolp (M.Sc.)Technical University of MunichChair of Electrical Energy Storage Technology
Tel: +49 89 289 26977e-mail: [email protected]
Team Battery Systems