Efficient split-step schemes for fluid–structure interaction involving incompressible generalised Newtonian flows

•Split-step fluid-structure interaction scheme allowing equal-order interpolation.•An added-mass-stable, semi-implicit, relaxed coupling yields fast convergence.•Incompressible generalised Newtonian fluid flows are considered.•A pressure Poisson equation with fully consistent boundary conditions is...

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Bibliographic Details
Published in:Computers & structures 2022-02, Vol.260, p.106718, Article 106718
Main Authors: Schussnig, Richard, Pacheco, Douglas R.Q., Fries, Thomas-Peter
Format: Article
Language:English
Subjects:
Algorithms
Aorta
Biomedical engineering
Blood flow
Dam construction
Design engineering
Elastic deformation
Fluid flow
Fluid-structure interaction
Fluids
Incompressible flow
Mathematical models
Newtonian fluids
Non Newtonian fluids
Non-Newtonian fluid
Semi-implicit coupling
Shear rate
Solvers
Split-step scheme
Time-splitting method
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Summary:•Split-step fluid-structure interaction scheme allowing equal-order interpolation.•An added-mass-stable, semi-implicit, relaxed coupling yields fast convergence.•Incompressible generalised Newtonian fluid flows are considered.•A pressure Poisson equation with fully consistent boundary conditions is derived.•Performance is shown via exact solutions, a benchmark and flow through an aneurysm. Blood flow, dam or ship construction and numerous other problems in biomedical and general engineering involve incompressible flows interacting with elastic structures. Such interactions heavily influence the deformation and stress states which, in turn, affect the engineering design process. Therefore, any reliable model of such physical processes must consider the coupling of fluids and solids. However, complexity increases for non-Newtonian fluid models, as used, e.g., for blood or polymer flows. In these fluids, subtle differences in the local shear rate can have a drastic impact on the flow and hence on the coupled problem. There, existing (semi-) implicit solution strategies based on split-step or projection schemes for Newtonian fluids are not applicable, while extensions to non-Newtonian fluids can lead to substantial numerical overhead depending on the chosen fluid solver. To address these shortcomings, we present here a higher-order accurate, added-mass-stable fluid–structure interaction scheme centered around a split-step fluid solver. We compare several implicit and semi-implicit variants of the algorithm and verify convergence in space and time. Numerical examples show good performance in both benchmarks and an idealised setting of blood flow through an abdominal aortic aneurysm considering physiological parameters.
ISSN:0045-7949
1879-2243
DOI:10.1016/j.compstruc.2021.106718