Stabilised Variational Multi-scale Finite Element Formulations for Viscoelastic Fluids

Stabilised Variational Multi-scale Finite Element Formulations for Viscoelastic Fluids

The objective of this article is to summarise the work that we have been doing as a group in the context of stabilised finite element formulations for viscoelastic fluid flows. Viscoelastic fluids are complex non-Newtonian fluids, characterised by having an irreducible constitutive equation that nee...

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Bibliographic Details
Published in:Archives of computational methods in engineering Vol. 28; no. 3; pp. 1987 - 2019
Main Authors: Castillo, Ernesto, Moreno, Laura, Baiges, Joan, Codina, Ramon
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-05-2021
Springer Nature B.V
Subjects:
Approximation
Computational fluid dynamics
Constitutive equations
Constitutive relationships
Context
Continuity equation
Engineering
Fluid flow
Formulations
Incompressible flow
Interpolation
Mathematical and Computational Engineering
Multiscale analysis
Newtonian fluids
Non Newtonian fluids
Nonlinearity
Numerical methods
Oscillations
Review Article
Velocity gradient
Viscoelastic fluids
Viscoelasticity
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Summary:The objective of this article is to summarise the work that we have been doing as a group in the context of stabilised finite element formulations for viscoelastic fluid flows. Viscoelastic fluids are complex non-Newtonian fluids, characterised by having an irreducible constitutive equation that needs to be solved coupled with the momentum and continuity equations. The finite element approximation of this kind of fluids presents several numerical difficulties. It inherits obviously the problems associated with the approximation of the incompressible Navier–Stokes equations. But, on top of that, now the constitutive equation is highly non-linear, with an advective term that may lead to both global and local oscillations in the numerical approximation. Moreover, even in the case of smooth solutions, it is necessary to meet some additional compatibility conditions between the velocity and the stress interpolation in order to ensure control over velocity gradients. The stabilised methods detailed in this work allow one to use equal order or even arbitrary interpolation for the problem unknowns ( σ - u - p ) (elastic deviatoric stress-velocity-pressure) and to stabilise dominant convective terms, and all of them can be framed in the context of variational multi-scale methods. Some additional numerical ingredients that are introduced in this article are the treatment of the non-linearities associated with the problem and the possibility to introduce a discontinuity-capturing technique to prevent local oscillations. Concerning the constitutive equation, both the standard as the logarithmic conformation reformulation are discussed for stationary and time-dependent problems, and different versions of stabilised finite element formulations are presented in both cases.
ISSN:1134-3060
1886-1784
DOI:10.1007/s11831-020-09526-x