Projecten per jaar
Samenvatting
A software framework for the solution of electrochemical processes will be presented.
In a first part the set of equations that are considered is given. It is explained that frequently used models are in fact subsets of these equations covering ion transport, electroosmotic flow on micro and nanometer scale, electrophoresis, MHD effects, ion transport influenced by a magnetic field &c..
It is further explained how the framework is structured in order to achieve this flexibility. The basis consists on grouping blocks of one or several equations that can be solved in an almost arbitrary sequence. For instance strongly coupled fields like flow and pressure (mass, momentum and energy conservation) or ion transport (mass conservation and electroneutrality) are solved simultaneously whereas the temperature field is often treated separately, or weakly coupled, it's effect spanning the other physics systems. These blocks can then be configuration such that they best suit the physics of a specific testcase.
Then aspects of numerical discretisation and also grid generation are highlighted. Finally typical examples will be treated. Ion transport under laminar and turbulent flow transport, electroosmotic flow, magnetic influence on ion transport and also the highly temperature dependent anodizing process.
In a first part the set of equations that are considered is given. It is explained that frequently used models are in fact subsets of these equations covering ion transport, electroosmotic flow on micro and nanometer scale, electrophoresis, MHD effects, ion transport influenced by a magnetic field &c..
It is further explained how the framework is structured in order to achieve this flexibility. The basis consists on grouping blocks of one or several equations that can be solved in an almost arbitrary sequence. For instance strongly coupled fields like flow and pressure (mass, momentum and energy conservation) or ion transport (mass conservation and electroneutrality) are solved simultaneously whereas the temperature field is often treated separately, or weakly coupled, it's effect spanning the other physics systems. These blocks can then be configuration such that they best suit the physics of a specific testcase.
Then aspects of numerical discretisation and also grid generation are highlighted. Finally typical examples will be treated. Ion transport under laminar and turbulent flow transport, electroosmotic flow, magnetic influence on ion transport and also the highly temperature dependent anodizing process.
Originele taal2  English 

Titel  59th Annual Meeting of the International Society of Electrochemistry 
Status  Published  sep 2008 
Evenement  Unknown  Duur: 1 sep 2008 → … 
Conference
Conference  Unknown 

Periode  1/09/08 → … 
Vingerafdruk
Duik in de onderzoeksthema's van 'A numerical framework for magnetoelectrochemistry'. Samen vormen ze een unieke vingerafdruk.Projecten
 1 Afgelopen

IWT232: Novel multiscale approach to transort phenomena in electrochemical processes (MUTECH)
Deconinck, J., Van Damme, S., Maciel, P., Van Parys, H., Deconinck, J., Hubin, A., Deconinck, H., Dick, E., Van Beeck, J., Fransaer, J., Carbonaro, M., Dekempeneer, E., Neerinck, D. & Van De Sande, C.
1/01/05 → 31/12/09
Project: Fundamenteel

The 59th Annual Meeting of the International Society of Electrochemistry
Gert Weyns (Speaker)
7 sep 2008 → 12 sep 2008Activiteit: Talk or presentation at a workshop/seminar

The 59th Annual Meeting of the International Society of Electrochemistry
Steven Van Damme (Speaker)
7 sep 2008 → 12 sep 2008Activiteit: Talk or presentation at a workshop/seminar

The 59th Annual Meeting of the International Society of Electrochemistry
Pedro MacIel (Participant)
7 sep 2008 → 12 sep 2008Activiteit: Participation in workshop, seminar