The challenge of service life prediction related corrosion …congress.cimne.com/icme2016/admin/files/filepaper/p74.pdf · 2016-05-09 · Electrochemistry •fracture mechanics corrosion
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The challenge of service life prediction related corrosion modelling
13th April 2015 / Barcelona
Daniel Höche 1, Eduardo Trindade 1, Mikhail L. Zheludkevich 1, Philippe Maincon 2, Ole Swang 3, Kamyab Zandi 4, Nils C. Bösch 5, Andreas Mittelbach 5, Theo Hack 6
1) Helmholtz-Zentrum Geesthacht Centre for Materials and Coastal Research, Institute of Materials Research, Germany
Complexity of modelling for service life
2
• statistical analysis • probalistic/heuristic
modelling • reliability models
Empirical models
• climate, geochemistry • corrosion tests • reservoirs
Environment
• phase fields • lattice-Boltzmann • mesoscale models
Microstructures
Multiphysiscs modelling
• Quantum chemistry • energy methods
Electronic models
Materials damage: • identification • monitoring • LCAA requirements
ICME ability
• Informatics • big data handling • validation
Architectures
• multiscale • interdisciplinary • hierarchical/embedded • shaping/deformation Corrosion
• multiscale • erosion • reactive flow
Fluid dynamics
• hydrogen/oxygen • passivity/electrode • pitting • crevice corrosion
Electrochemistry
• fracture mechanics • corrosion fatigue • integrity studies
Damage mechanics
• chemical reactions • surface chemistry • speciation
• DFT / MD methods • dislocations • interface models
Atomistic scale Thermodynamics
D. Zander, D. Höche, J. Deconinck, T. Hack, 2015. Corrosion and its context to Service-Life, Chapter in Handbook of Software Solutions for ICME , August 2016.
Service-Life Design (SLD) during digital Engineering linking and coupling of materials entities and scales
model input
Target: Processing
An example – Pitting / liquid film (with flow)
3
• statistical analysis • probalistic/heuristic
modelling • reliability models
Empirical models
• climate, geochemistry • corrosion tests • reservoirs
Environment
• phase fields • lattice-Boltzmann • mesoscale models
Microstructures
Multiphysiscs modelling
• Quantum chemistry • energy methods
Electronic models
Materials damage: • identification • monitoring • LCAA requirements
ICME ability
• Informatics • big data handling • validation
Architectures
• multiscale • interdisciplinary • hierarchical/embedded • shaping/deformation Corrosion
• multiscale • erosion • reactive flow
Fluid dynamics
• hydrogen/oxygen • passivity/electrode • pitting • crevice corrosion
Electrochemistry
• fracture mechanics • corrosion fatigue • integrity studies
Damage mechanics
• chemical reactions • surface chemistry • speciation
• DFT / MD methods • dislocations • interface models
Atomistic scale Thermodynamics
pitting t1
t2 t3
electrochemistry CFD atomistic modelling damage mechanics ….. (many more)
daniel.hoeche@hzg.de
Aims of current simulation action
4
Idea behind Corrosion meets materials simulation
Assisting engineers and scientists
by quantitative studies and process parameter weighting
by modelling corrosion properties based on equations
Economic aspects - Reduction of development expenses and periods,
and improved planning ability due to tailored properties
improved predictive power for e.g. for engineering materials and its
corrosion properties
establishing of materials design at the PC by e.g. phase field modelling
with the target property: corrosion and degradation rate for implants
but also e.g. batteries
daniel.hoeche@hzg.de
Challenge – service life vs. corrosion control
5
100 m 10-3 10-6 10-9
macroscale
mesoscale
microscale
capacitive double layer (Helmholtz layer)
Corrosion for Science and Engineering by K. R. Trethewey et.al 1995
macrogalvanic corrosion microgalvanic corrosion
filiform corrosion
pitting
uniform corrosion – chemical conversion
t1 t
2 t3
1 cm
minimizing e.g. surface engineering effort enhanced component failure control scaling aspects
daniel.hoeche@hzg.de
Scaling- and methodological aspects
6
multiple methods (DFT, MD CA, GC FEM, BEM) time scaling (from fs to years) interoperability
daniel.hoeche@hzg.de
Example: Reinforced concrete service life
7
homogenisation along the scales linking discrete - continuum
EU - LORCENIS
Cl- ingress for 25 years
daniel.hoeche@hzg.de
Example: Galvanic issues – Lightweight design
8
Model matchesdeposit profile!a b
c
2 mm
8 mm0
1
2
3
4
5
6
7
8
J (A
/m²)
0 5 10 15 20 25
420
X (mm)Y
(mm
)
420Y
(mm
)
8 mm
2 mm A 6 mm difference in the distancebetween the screw and the Mg sheet edge causes the corrosioncurrent to more than double!
joint design for multi material assemblies big data and validation issue
EU - ProAir corrosion product deposit and Icorr Multi-material joint layout
daniel.hoeche@hzg.de
Example: Coatings and tests
9
accelerated corrosion testing(e.g. delamination in climatechamber test)
short developmental periods
Source:
hot-dip galvanized steel
daniel.hoeche@hzg.de
Example: Magnesium alloys
10
Mg sheets
Mg forgings
Mg castings Life cycle (service life) prediction of magnesium alloys
Li et al. Biomaterials 29(2008) 1329
Schreckenberger et al. Mat. und We. 41(2010) 853
Transportation
Medicine
Service life
Batteries
daniel.hoeche@hzg.de
Aims of “predictive” materials simulation action
11
Interdisciplinarity – microstructures meet electrochemistry scaling aspects data exchange issue
daniel.hoeche@hzg.de
System Mg-Al A multiscale problem
12
Monas, A., Shchyglo, O., Kim, S. J., Yim, C. D., Höche, D., & Steinbach, I. (2015). Divorced Eutectic Solidification of Mg-Al Alloys. JOM, 1-7.
towards microstructure – corrosion coupling
daniel.hoeche@hzg.de
State of the art – microstructure vs. corrosion
13
phase field calculations simulate Mg-Al microstructure
formation at different processing conditions primary, cooling rate sensitive α-phase nucleation secondary β-phase nucleation in channels divorced eutectic α+β growth
tertiary nucleation inside residual melt-channels recover the transition from divorced to lamellar eutectic
Scheil ?
beta meshwork offering improved corrosion resistance
I0 = 1mA
reality
daniel.hoeche@hzg.de
Next step – Linking to simulation of corrosion mechanisms
14
Höche et al. CIT. 12(2013) 1951
Replacement of experiments
5 K/s 25 K/s
daniel.hoeche@hzg.de
Research challange: Service-Life Design (SLD) during virtual design period
Goal: Establishment of full chain predictive modelling towards CAx considering service-life aspects
Perspective – progress in digitalization
15
Processing
Materials properties Service-life exposure (described via corrosion test)
Full chain corrosion model
Service-life prediction (maintenance cycles)
CAE feedback
daniel.hoeche@hzg.de
Transfer into an ICME approach
16
Thermodynamic database
Electrochemical database
Corrosion model
ICME – approach ANY SUGGESTIONS?
Optimized raw material for application
e.g. ???
Issues
daniel.hoeche@hzg.de
Possibilities, Requirements and Limits
17
Possibilities
Establishment of a CAE like assisting tool for material development
Determination of material parameters without expensive examinations
Long term cost reduction and improved service life assessment
(e.g. maintenance cycles)
Requirements
Integration of databases multidisciplinary interaction and interoperability
Limits
Box simulation due to limited computing power – HPC extension
Need of well-known environmental conditions – validation
Simulation of test conditions which describes service life – e.g. VDA
daniel.hoeche@hzg.de 18
Thank you
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