Publication:
Numerical FSI investigation based on LES: Flow past a cylinder with a flexible splitter plate involving large deformations (FSI-PfS-2a)

cris.customurl8999
cris.virtual.departmentStrömungsmechanik
cris.virtual.departmentStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtualsource.department6758246f-6106-494c-b0aa-fb96d0de1ce7
cris.virtualsource.departmentba61e71a-d073-4609-89b6-c10b460b09a8
dc.contributor.authorDe Nayer, Guillaume
dc.contributor.authorBreuer, Michael
dc.date.issued2014-12
dc.description.abstract© 2014 Elsevier Inc. The objective of this paper is to provide a detailed numerical investigation on the fluid-structure interaction (FSI) test case presented in Kalmbach and Breuer (J. of Fluids and Structures, 42, (2013), 369-387). It relies on detailed experimental investigations on the fluid flow and the structure deformation using modern optical measurement techniques such as particle-image velocimetry and laser triangulation sensors. The present numerical study is based on an efficient partitioned FSI coupling scheme especially developed for turbulent flow simulations around light-weight structures using large-eddy simulation. The current FSI configuration is composed of a fixed cylinder with a flexible thin rubber plate and a rear mass inducing a turbulent flow (Re. =. 30,470). Mainly based on a movement-induced excitation the flexible structure oscillates in the second swiveling mode involving large deformations. Thus, particular attention has been paid to the computational model and the numerical set-up. Special seven-parameters shell elements are applied to precisely model the flexible structure. Structural tests are carried out to approximate the optimal structural parameters. A fine and smooth fluid mesh has been generated in order to correctly predict the wide range of different flow structures presents near and behind the flexible rubber plate. A phase-averaging is applied to the numerical results obtained, so that they can be compared with the phase-averaged experimental data. Both are found to be in close agreement exhibiting a structure deformation in the second swiveling mode with similar frequencies and amplitudes. Finally, a sensitivity study is carried out to show the influence of different physical parameters (e.g. Young's modulus) and modeling aspects (e.g.subgrid-scale model) on the FSI phenomenon.
dc.description.versionNA
dc.identifier.citationIn: The international journal of heat and fluid flow. - New York, NY [u.a.] : Elsevier, 1979- ; ZDB-ID: 759894-4 . - Bd. 50.2014, Seite 300-315
dc.identifier.doi10.1016/j.ijheatfluidflow.2014.08.013
dc.identifier.issn0142-727X
dc.identifier.scopus2-s2.0-84911114872
dc.identifier.urihttps://openhsu.ub.hsu-hh.de/handle/10.24405/8999
dc.language.isoen
dc.publisherElsevier
dc.relation.journalInternational Journal of Heat and Fluid Flow
dc.relation.orgunitStrömungsmechanik
dc.rights.accessRightsmetadata only access
dc.titleNumerical FSI investigation based on LES: Flow past a cylinder with a flexible splitter plate involving large deformations (FSI-PfS-2a)
dc.typeResearch article
dcterms.bibliographicCitation.originalpublisherplaceNew York, NY
dspace.entity.typePublication
hsu.peerReviewed
hsu.uniBibliography
oaire.citation.endPage315
oaire.citation.startPage300
oaire.citation.volume50
Files