Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets

Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets

We propose to model ice shedding trajectories by an innovative paradigm that is based on cartesian grids, penalization and level sets. The use of cartesian grids bypasses the meshing issue, and penalization is an efficient alternative to explicitly impose boundary conditions so that the body-fitted...

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Main Authors: Héloïse Beaugendre, François Morency, Federico Gallizio, Sophie Laurens
Format: Article
Language:English
Published: Hindawi Limited 2011-01-01
Series:Modelling and Simulation in Engineering
Online Access:http://dx.doi.org/10.1155/2011/274947
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spelling doaj-0fd8213eab1d4a29bd145e2942d646552020-11-24T23:52:56ZengHindawi LimitedModelling and Simulation in Engineering1687-55911687-56052011-01-01201110.1155/2011/274947274947Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level SetsHéloïse Beaugendre0François Morency1Federico Gallizio2Sophie Laurens3IPB, Université de Bordeaux, INRIA Bordeaux Sud-Ouest, Equipe-Projet MC2, IMB UMR 5251, 351 Cours de la Libération, 33405 Talence, FranceDépartement de Génie Mécanique, École de Technologie Supérieure, 1100 Rue Notre-Dame Ouest, Montréal, QC, H3C 1K3, CanadaOptimad Engineering s.r.l., Via Giacinto Collegno, 18, 10143 Turin, ItalyUniversité de Bordeaux, INRIA Bordeaux Sud-Ouest, Equipe-Projet MC2, IMB UMR 5251, 351 Cours de la Libération, 33405 Talence, FranceWe propose to model ice shedding trajectories by an innovative paradigm that is based on cartesian grids, penalization and level sets. The use of cartesian grids bypasses the meshing issue, and penalization is an efficient alternative to explicitly impose boundary conditions so that the body-fitted meshes can be avoided, making multifluid/multiphysics flows easy to set up and simulate. Level sets describe the geometry in a nonparametric way so that geometrical and topological changes due to physics and in particular shed ice pieces are straight forward to follow. The model results are verified against the case of a free falling sphere. The capabilities of the proposed model are demonstrated on ice trajectories calculations for flow around iced cylinder and airfoil.http://dx.doi.org/10.1155/2011/274947
collection DOAJ
language English
format Article
sources DOAJ
author Héloïse Beaugendre
François Morency
Federico Gallizio
Sophie Laurens
spellingShingle Héloïse Beaugendre
François Morency
Federico Gallizio
Sophie Laurens
Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets
Modelling and Simulation in Engineering
author_facet Héloïse Beaugendre
François Morency
Federico Gallizio
Sophie Laurens
author_sort Héloïse Beaugendre
title Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets
title_short Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets
title_full Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets
title_fullStr Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets
title_full_unstemmed Computation of Ice Shedding Trajectories Using Cartesian Grids, Penalization, and Level Sets
title_sort computation of ice shedding trajectories using cartesian grids, penalization, and level sets
publisher Hindawi Limited
series Modelling and Simulation in Engineering
issn 1687-5591
1687-5605
publishDate 2011-01-01
description We propose to model ice shedding trajectories by an innovative paradigm that is based on cartesian grids, penalization and level sets. The use of cartesian grids bypasses the meshing issue, and penalization is an efficient alternative to explicitly impose boundary conditions so that the body-fitted meshes can be avoided, making multifluid/multiphysics flows easy to set up and simulate. Level sets describe the geometry in a nonparametric way so that geometrical and topological changes due to physics and in particular shed ice pieces are straight forward to follow. The model results are verified against the case of a free falling sphere. The capabilities of the proposed model are demonstrated on ice trajectories calculations for flow around iced cylinder and airfoil.
url http://dx.doi.org/10.1155/2011/274947
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AT francoismorency computationoficesheddingtrajectoriesusingcartesiangridspenalizationandlevelsets
AT federicogallizio computationoficesheddingtrajectoriesusingcartesiangridspenalizationandlevelsets
AT sophielaurens computationoficesheddingtrajectoriesusingcartesiangridspenalizationandlevelsets
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