Multiscale simulations of three-dimensional viscoelastic flows in a square-square contraction
Multiscale simulations of three-dimensional viscoelastic flows in a square-square contraction
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03.2015Publisher
Institut für Numerische Simulation (INS)Publisher Location
BonnMetadata
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Citable Link (Handle URI) 
https://hdl.handle.net/20.500.11811/11929
Abstract
We apply the multiscale FENE model to a 3D square-square contraction flow problem and to two 2D benchmark experiments. For this purpose, we couple the stochastic Brownian configuration field method (BCF) with our fully parallelized three-dimensional Navier-Stokes solver NaSt3DGPF. The robustness of the BCF method enables the numerical simulation of higher Deborah number flows for which most macroscopic methods suffer from stability issues. We validate our implementation by investigating the numerical error for a 2D viscoelastic Poiseuille flow that has an analytical solution. Furthermore, we compare the FENE model with the FENE-P closure for a two-dimensional 4 : 1 contraction flow. We then compare the results of our 3D simulations with that of experimental measurements from literature and obtain a very good agreement. In particular, we are able to reproduce effects such as strong vortex enhancement, streamline divergence and flow inversion for highly elastic flows. Due to their computational complexity, our simulations require massively parallel computations. To this end, we use a domain decomposition approach with MPI.
Subjects
multiscale simulation, micro-macro method, Brownian configuration fields, FENE dumbbell, 3D contraction flow, high-performance computing
Classification (DDC)
510 Mathematik 518 Numerische AnalysisFirst Publication
https://ins.uni-bonn.de/publication/preprintsRelated Publications
https://doi.org/10.1016/j.jnnfm.2014.01.004Part of Series
INS Preprints ; 1313Griebel, Michael; Rüttgers, Alexander: Multiscale simulations of three-dimensional viscoelastic flows in a square-square contraction. In: INS Preprints, 1313.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11929
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11929
@unpublished{handle:20.500.11811/11929,
author = {{Michael Griebel} and {Alexander Rüttgers}},
title = {Multiscale simulations of three-dimensional viscoelastic flows in a square-square contraction},
publisher = {Institut für Numerische Simulation (INS)},
year = 2015,
month = mar,
INS Preprints},
volume = 1313,
note = {We apply the multiscale FENE model to a 3D square-square contraction flow problem and to two 2D benchmark experiments. For this purpose, we couple the stochastic Brownian configuration field method (BCF) with our fully parallelized three-dimensional Navier-Stokes solver NaSt3DGPF. The robustness of the BCF method enables the numerical simulation of higher Deborah number flows for which most macroscopic methods suffer from stability issues. We validate our implementation by investigating the numerical error for a 2D viscoelastic Poiseuille flow that has an analytical solution. Furthermore, we compare the FENE model with the FENE-P closure for a two-dimensional 4 : 1 contraction flow. We then compare the results of our 3D simulations with that of experimental measurements from literature and obtain a very good agreement. In particular, we are able to reproduce effects such as strong vortex enhancement, streamline divergence and flow inversion for highly elastic flows. Due to their computational complexity, our simulations require massively parallel computations. To this end, we use a domain decomposition approach with MPI.},
url = {https://hdl.handle.net/20.500.11811/11929}
}
author = {{Michael Griebel} and {Alexander Rüttgers}},
title = {Multiscale simulations of three-dimensional viscoelastic flows in a square-square contraction},
publisher = {Institut für Numerische Simulation (INS)},
year = 2015,
month = mar,
INS Preprints},
volume = 1313,
note = {We apply the multiscale FENE model to a 3D square-square contraction flow problem and to two 2D benchmark experiments. For this purpose, we couple the stochastic Brownian configuration field method (BCF) with our fully parallelized three-dimensional Navier-Stokes solver NaSt3DGPF. The robustness of the BCF method enables the numerical simulation of higher Deborah number flows for which most macroscopic methods suffer from stability issues. We validate our implementation by investigating the numerical error for a 2D viscoelastic Poiseuille flow that has an analytical solution. Furthermore, we compare the FENE model with the FENE-P closure for a two-dimensional 4 : 1 contraction flow. We then compare the results of our 3D simulations with that of experimental measurements from literature and obtain a very good agreement. In particular, we are able to reproduce effects such as strong vortex enhancement, streamline divergence and flow inversion for highly elastic flows. Due to their computational complexity, our simulations require massively parallel computations. To this end, we use a domain decomposition approach with MPI.},
url = {https://hdl.handle.net/20.500.11811/11929}
}
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