On the wall boundary conditions for species-specific mass conservation equations in mathematical modelling of direct precipitation fouling from supersaturated, multi-component fluid mixtures

On the wall boundary conditions for species-specific mass conservation equations in mathematical modelling of direct precipitation fouling from supersaturated, multi-component fluid mixtures

The mathematical modelling of species transport in the turbulent boundary layer of fluids that precipitate on the wall, is an important topic at the heart of one of the biggest challenges in efficient energy utilization in all process industries; namely the fouling of heat exchangers. A major contri...

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Veröffentlicht in:arXiv.org 2017-03
Hauptverfasser: Johnsen, S G, Pääkkönen, T M, Andersson, S, Johansen, S T, Wittgens, B
Format: Artikel
Sprache:eng
Schlagworte:
Atomic properties
Boundary conditions
Boundary layer
Computational fluid dynamics
Conservation equations
Energy utilization
Fluid flow
Fouling
Heat exchangers
Mathematical analysis
Mathematical models
Transport phenomena
Turbulent boundary layer
Wildlife conservation
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Zusammenfassung:The mathematical modelling of species transport in the turbulent boundary layer of fluids that precipitate on the wall, is an important topic at the heart of one of the biggest challenges in efficient energy utilization in all process industries; namely the fouling of heat exchangers. A major contributor to the complexity of the problem is the multi-length-scale nature of the governing phenomena. That is, transport mechanisms dominating at the nano-scale may be responsible for the macroscopic performance of the industrial process. This paper addresses some of the challenges that need to be met in modelling the boundary conditions, i.e. the atomic/molecular-scale conditions, for the species-specific mass conservation equations, at the wall, for single-phase, multi-component fluids that precipitate at the wall.
ISSN:2331-8422