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On stability and relaxation techniques for partitioned fluid-structure interaction simulations
  • Johan Lorentzon,
  • Johan Revstedt
Johan Lorentzon
Lunds Universitet Kemicentrum

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Johan Revstedt
LTH
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Abstract

The stability of relaxation techniques has been studied for strongly coupled fluid-structure interaction (FSI) with application to a cantilever immersed in channel flow. The fluid is governed by Navier-Stokes equations for incompressible flow condition using turbulence modelling and the solid is governed by the equation of motion with compressible material modelling. The applied kinematic description is Lagrangian for the solid and Eulerian for the fluid. The coupling of the state solvers is achieved by the Arbitrary Lagrange-Euler procedure which involves a mesh motion solver and the FSI procedure is stabilised by relaxation. It is shown that the stability can be related to the frequency shift caused by FSI and they follow the same rate for the shape factor of the structure with an offset. This correlates well to theoretical results but also show that for given mesh resolution, all relaxations fail for sufficient high-frequency shift. We also propose a continuation technique to stabilise the solution near the instability region, which also improves the efficiency and can be integrated easily for the black-box FSI solution procedure.
04 Dec 2021Submitted to Engineering Reports
07 Dec 2021Submission Checks Completed
07 Dec 2021Assigned to Editor
07 Dec 2021Reviewer(s) Assigned
27 Dec 2021Editorial Decision: Revise Major
25 Feb 20221st Revision Received
25 Feb 2022Submission Checks Completed
25 Feb 2022Assigned to Editor
25 Feb 2022Reviewer(s) Assigned
21 Mar 2022Editorial Decision: Accept
17 Apr 2022Published in Engineering Reports. 10.1002/eng2.12514