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| style="background-color:LightGrey;"|Charles Mockett
| style="background-color:LightGrey;"|Charles Mockett
| style="background-color:LightGrey;"|CFD Software GmbH and Technische Universitaet Berlin
| style="background-color:LightGrey;"|CFD Software GmbH and Technische Universitaet Berlin
|- style="background-color:LightGrey;"
|- style="background-color:#AED7FF;"
| || Michael Strelets
| || style="background-color:LightGrey;"|Michael Strelets
| New Technologies and Services LLC (NTS) and St.-Petersburg State Polytechnic University
| style="background-color:LightGrey;"|New Technologies and Services LLC (NTS) and St.-Petersburg State Polytechnic University


|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !! style="background-color:silver;"|2-12
! !! style="background-color:LightGrey;"|2-12
| style="background-color:silver;"|[[UFR_2-12|Turbulent Flow Past Two-Body Configurations]] [[Image:Star_red.jpg]]
| style="background-color:LightGrey;"|[[UFR_2-12|Turbulent Flow Past Two-Body Configurations]]<!--[[Image:Star_red.jpg]]-->
| style="background-color:silver;"|A.&nbsp;Garbaruk, M.&nbsp;Shur and M.&nbsp;Strelets
| style="background-color:LightGrey;"|A.&nbsp;Garbaruk, M.&nbsp;Shur and M.&nbsp;Strelets
| style="background-color:silver;"|New Technologies and Services LLC (NTS) and St.-Petersburg State Polytechnic University
| style="background-color:LightGrey;"|New Technologies and Services LLC (NTS) and St.-Petersburg State Polytechnic University
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !!style="background-color:silver;"|2-13
! !!style="background-color:LightGrey;"|2-13
| style="background-color:silver;"|[[UFR_2-13|Fluid-structure interaction in turbulent flow past cylinder/plate configuration I (First swiveling mode)]][[Image:Star_red.jpg]]
| style="background-color:LightGrey;"|[[UFR_2-13|Fluid-structure interaction in turbulent flow past cylinder/plate configuration I (First swiveling mode)]]<!--[[Image:Star_red.jpg]]-->
| style="background-color:silver;"|Michael&nbsp;Breuer
| style="background-color:LightGrey;"|Michael&nbsp;Breuer
| style="background-color:silver;"|Helmut-Schmidt Universität Hamburg
| style="background-color:LightGrey;"|Helmut-Schmidt Universität Hamburg
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !!style="background-color:silver;"|2-14
! !!style="background-color:LightGrey;"|2-14
| style="background-color:silver;"|[[UFR_2-14|Fluid-structure interaction in turbulent flow past cylinder/plate configuration II (Second swiveling mode)]][[Image:Star_red.jpg]]
| style="background-color:LightGrey;"|[[UFR_2-14|Fluid-structure interaction in turbulent flow past cylinder/plate configuration II (Second swiveling mode)]]<!--[[Image:Star_red.jpg]]-->
| style="background-color:silver;"|Andreas&nbsp;Kalmbach, Guillaume&nbsp;De&nbsp;Nayer, Michael&nbsp;Breuer
| style="background-color:LightGrey;"|Andreas&nbsp;Kalmbach, Guillaume&nbsp;De&nbsp;Nayer, Michael&nbsp;Breuer
| style="background-color:silver;"|Helmut-Schmidt Universität Hamburg
| style="background-color:LightGrey;"|Helmut-Schmidt Universität Hamburg
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !!style="background-color:silver;"|2-15
! !!style="background-color:LightGrey;"|2-15
| style="background-color:silver;"|[[UFR_2-15|Benchmark on the Aerodynamics of a Rectangular 5:1 Cylinder (BARC)]]
| style="background-color:LightGrey;"|[[UFR_2-15|Benchmark on the Aerodynamics of a Rectangular 5:1 Cylinder (BARC)]]
| style="background-color:silver;"|Luca&nbsp;Bruno, Maria&nbsp;Vittoria&nbsp;Salvetti
| style="background-color:LightGrey;"|Luca&nbsp;Bruno, Maria&nbsp;Vittoria&nbsp;Salvetti
| style="background-color:silver;"|Politecnico&nbsp;di&nbsp;Torino,&nbsp;Università&nbsp;di&nbsp;Pisa
| style="background-color:LightGrey;"|Politecnico&nbsp;di&nbsp;Torino,&nbsp;Università&nbsp;di&nbsp;Pisa
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
![[Semi-confined_Flows|Semi-confined Flows]] !! !! !! !!  
![[Semi-confined_Flows|Semi-confined Flows]] !! !! !! !!  
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-01
!  !! style="background-color:LightGrey;"|3-01
| style="background-color:gold;"|[[Boundary layer interacting with wakes under adverse pressure gradient - NLR 7301 high lift configuration]] || style="background-color:gold;"| Jan Vos || style="background-color:gold;"| CFS Engineering SA
| style="background-color:LightGrey;"|[[Boundary layer interacting with wakes under adverse pressure gradient - NLR 7301 high lift configuration]] || style="background-color:LightGrey;"| Jan Vos || style="background-color:LightGrey;"| CFS Engineering SA
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-03
!  !! style="background-color:LightGrey;"|3-03
| style="background-color:gold;"|[[2D Boundary layers with pressure gradients (A)]] || style="background-color:gold;"| Florian Menter || style="background-color:gold;"| AEA Technology
| style="background-color:LightGrey;"|[[2D Boundary layers with pressure gradients (A)]] || style="background-color:LightGrey;"| Florian Menter || style="background-color:LightGrey;"| AEA Technology
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-04  
!  !! style="background-color:LightGrey;"|3-04  
| style="background-color:gold;"|[[Laminar-turbulent boundary layer transition]] || style="background-color:gold;"| Andrzej Boguslawski || style="background-color:gold;"| Technical University of Czestochowa
| style="background-color:LightGrey;"|[[Laminar-turbulent boundary layer transition]] || style="background-color:LightGrey;"| Andrzej Boguslawski || style="background-color:LightGrey;"| Technical University of Czestochowa
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-05  
!  !! style="background-color:LightGrey;"|3-05  
| style="background-color:gold;"|[[Shock/boundary-layer interaction (on airplanes)]] || style="background-color:gold;"| Anthony Hutton || style="background-color:gold;"| Qinetiq
| style="background-color:LightGrey;"|[[Shock/boundary-layer interaction (on airplanes)]] || style="background-color:LightGrey;"| Anthony Hutton || style="background-color:LightGrey;"| Qinetiq
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-06  
!  !! style="background-color:LightGrey;"|3-06  
| style="background-color:gold;"|[[Natural and mixed convection boundary layers on vertical heated walls (A)]] || style="background-color:gold;"| André Latrobe || style="background-color:gold;"| CEA / DRN / Department de Thermohydraulique
| style="background-color:LightGrey;"|[[Natural and mixed convection boundary layers on vertical heated walls (A)]] || style="background-color:LightGrey;"| André Latrobe || style="background-color:LightGrey;"| CEA / DRN / Department de Thermohydraulique
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-07  
!  !! style="background-color:LightGrey;"|3-07  
| style="background-color:silver;"|[[Natural and mixed convection boundary layers on vertical heated walls (B)]] || style="background-color:silver;"| Mike Rabbitt || style="background-color:silver;"| British Energy
| style="background-color:LightGrey;"|[[Natural and mixed convection boundary layers on vertical heated walls (B)]] || style="background-color:LightGrey;"| Mike Rabbitt || style="background-color:LightGrey;"| British Energy
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-08  
!  !! style="background-color:LightGrey;"|3-08  
| style="background-color:silver;"|[[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation]] || style="background-color:silver;"| Pietro Catalano || style="background-color:silver;"| CIRA
| style="background-color:LightGrey;"|[[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation]] || style="background-color:LightGrey;"| Pietro Catalano || style="background-color:LightGrey;"| CIRA
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-09  
!  !! style="background-color:LightGrey;"|3-09  
| style="background-color:gold;"|[[Impinging jet]] || style="background-color:gold;"| Jean-Paul Bonnet, Remi Manceau || style="background-color:gold;"| Université de Poitiers
| style="background-color:LightGrey;"|[[Impinging jet]] || style="background-color:LightGrey;"| Jean-Paul Bonnet, Remi Manceau || style="background-color:LightGrey;"| Université de Poitiers
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-10  
!  !! style="background-color:LightGrey;"|3-10  
| style="background-color:silver;"|[[The plane wall jet]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Jan Eriksson, Rolf Karlsson || style="background-color:silver;"| Vattenfall Utveckling AB
| style="background-color:LightGrey;"|[[The plane wall jet]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Jan Eriksson, Rolf Karlsson || style="background-color:LightGrey;"| Vattenfall Utveckling AB
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-11  
!  !! style="background-color:LightGrey;"|3-11  
| style="background-color:silver;"|[[Pipe expansion (with heat transfer)]] || style="background-color:silver;"| Jeremy Noyce || style="background-color:silver;"| Magnox Electric
| style="background-color:LightGrey;"|[[Pipe expansion (with heat transfer)]] || style="background-color:LightGrey;"| Jeremy Noyce || style="background-color:LightGrey;"| Magnox Electric
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-12  
!  !! style="background-color:LightGrey;"|3-12  
| style="background-color:silver;"|[[Stagnation point flow]] || style="background-color:silver;"| Beat Ribi || style="background-color:silver;"| MAN Turbomaschinen AG Schweiz
| style="background-color:LightGrey;"|[[Stagnation point flow]] || style="background-color:LightGrey;"| Beat Ribi || style="background-color:LightGrey;"| MAN Turbomaschinen AG Schweiz
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-13  
!  !! style="background-color:LightGrey;"|3-13  
| style="background-color:silver;"|[[Flow over an isolated hill (without dispersion)]] || style="background-color:silver;"| Frederic Archambeau || style="background-color:silver;"| EDF - R&D Division
| style="background-color:LightGrey;"|[[Flow over an isolated hill (without dispersion)]] || style="background-color:LightGrey;"| Frederic Archambeau || style="background-color:LightGrey;"| EDF - R&D Division
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-14  
!  !! style="background-color:LightGrey;"|3-14  
| style="background-color:silver;"|[[Flow over surface-mounted cube/rectangular obstacles]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Ian Castro || style="background-color:silver;"| University of Southampton
| style="background-color:LightGrey;"|[[Flow over surface-mounted cube/rectangular obstacles]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Ian Castro || style="background-color:LightGrey;"| University of Southampton
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|3-15  
!  !! style="background-color:LightGrey;"|3-15  
| style="background-color:gold;"|[[2D flow over backward facing step]] || style="background-color:gold;"| Arnau Duran || style="background-color:gold;"| CIMNE
| style="background-color:LightGrey;"|[[2D flow over backward facing step]] || style="background-color:LightGrey;"| Arnau Duran || style="background-color:LightGrey;"| CIMNE
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|3-18  
!  !! style="background-color:LightGrey;"|3-18  
| style="background-color:silver;"|[[2D Boundary layers with pressure gradients (B)]] || style="background-color:silver;"| Fred Mendonca || style="background-color:silver;"| Computational Dynamics Ltd
| style="background-color:LightGrey;"|[[2D Boundary layers with pressure gradients (B)]] || style="background-color:LightGrey;"| Fred Mendonca || style="background-color:LightGrey;"| Computational Dynamics Ltd
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !! style="background-color:silver;"|3-30
! !! style="background-color:LightGrey;"|3-30
| style="background-color:silver;"|[[UFR_3-30|2D Periodic Hill Flow]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Christoph Rapp, Michael Breuer, Michael Manhart, Nikolaus Peller
| style="background-color:LightGrey;"|[[UFR_3-30|2D Periodic Hill Flow]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Christoph Rapp, Michael Breuer, Michael Manhart, Nikolaus Peller
| style="background-color:silver;"| Technische Universität München, Helmut-Schmidt Universität Hamburg
| style="background-color:LightGrey;"| Technische Universität München, Helmut-Schmidt Universität Hamburg
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
! !!- style="background-color:silver;"|3-31
! !!- style="background-color:LightGrey;"|3-31
| style="background-color:silver;"|[[UFR_3-31|Flow over curved backward-facing step]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Sylvain Lardeau
| style="background-color:LightGrey;"|[[UFR_3-31|Flow over curved backward-facing step]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Sylvain Lardeau
| style="background-color:silver;"| CD-adapco, London, UK
| style="background-color:LightGrey;"| CD-adapco, London, UK
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !!- style="background-color:silver;"|3-32
! !!- style="background-color:LightGrey;"|3-32
| style="background-color:silver;"|[[UFR_3-32|Planar shock-wave boundary-layer interaction]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Jean-Paul Dussauge, P. Dupont, N. Sandham, E. Garnier
| style="background-color:LightGrey;"|[[UFR_3-32|Planar shock-wave boundary-layer interaction]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Jean-Paul Dussauge, P. Dupont, N. Sandham, E. Garnier
| style="background-color:silver;"| Aix-Marseille Université and Centre National de la Recherche Scientifique UM 7343,&nbsp;University of Southampton,&nbsp;ONERA/DAAP
| style="background-color:LightGrey;"| Aix-Marseille Université and Centre National de la Recherche Scientifique UM 7343,&nbsp;University of Southampton,&nbsp;ONERA/DAAP
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !!- style="background-color:silver;"|3-33
! !!- style="background-color:LightGrey;"|3-33
| style="background-color:silver;"|[[UFR_3-33|Turbulent flow past a wall-mounted hemisphere]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Jens Nikolas Wood, Guillaume De Nayer, Stephan Schmidt, Michael Breuer
| style="background-color:LightGrey;"|[[UFR_3-33|Turbulent flow past a wall-mounted hemisphere]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Jens Nikolas Wood, Guillaume De Nayer, Stephan Schmidt, Michael Breuer
| style="background-color:silver;"|  Helmut-Schmidt Universität Hamburg
| style="background-color:LightGrey;"|  Helmut-Schmidt Universität Hamburg
|-
|- style="background-color:#AED7FF;"
! !!- style="background-color:LightGrey;"|3-34
| style="background-color:LightGrey;"|[[UFR_3-34|Smooth wall separation and reattachment at high Reynolds numbers]]
| style="background-color:LightGrey;"|E. Guseva, M. Strelets
| style="background-color:LightGrey;"|Peter the Great St Petersburg Polytechnic University
|-
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
![[Confined_Flows|Confined Flows]] !! !! !! !!  
![[Confined_Flows|Confined Flows]] !! !! !! !!  
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-02   
!  !! style="background-color:LightGrey;"|4-02   
| style="background-color:silver;"|[[Confined coaxial swirling jets]] || style="background-color:silver;"| Stefan Hohmann || style="background-color:silver;"| MTU Aero Engines
| style="background-color:LightGrey;"|[[Confined coaxial swirling jets]] || style="background-color:LightGrey;"| Stefan Hohmann || style="background-color:LightGrey;"| MTU Aero Engines
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-03    
!  !! style="background-color:LightGrey;"|4-03    
| style="background-color:silver;"|[[Pipe flow - rotating]] || style="background-color:silver;"| Paolo Orlandi, Stefano Leonardi || style="background-color:silver;"| Universita di Roma 'La Sapienza'
| style="background-color:LightGrey;"|[[Pipe flow - rotating]] || style="background-color:LightGrey;"| Paolo Orlandi, Stefano Leonardi || style="background-color:LightGrey;"| Universita di Roma 'La Sapienza'
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|4-04    
!  !! style="background-color:LightGrey;"|4-04    
| style="background-color:gold;"|[[Flow in a curved rectangular duct - non rotating]] || style="background-color:gold;"| Lewis Davenport || style="background-color:gold;"| Rolls-Royce Marine Power, Engineering & Technology Division
| style="background-color:LightGrey;"|[[Flow in a curved rectangular duct - non rotating]] || style="background-color:LightGrey;"| Lewis Davenport || style="background-color:LightGrey;"| Rolls-Royce Marine Power, Engineering & Technology Division
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-05    
!  !! style="background-color:LightGrey;"|4-05    
| style="background-color:silver;"|[[Curved passage flow]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Nouredine Hakimi || style="background-color:silver;"| NUMECA International
| style="background-color:LightGrey;"|[[Curved passage flow]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Nouredine Hakimi || style="background-color:LightGrey;"| NUMECA International
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-06    
!  !! style="background-color:LightGrey;"|4-06    
| style="background-color:silver;"|[[Swirling diffuser flow]] || style="background-color:silver;"| Chris Carey ||  style="background-color:silver;"| Fluent Europe Ltd
| style="background-color:LightGrey;"|[[Swirling diffuser flow]] || style="background-color:LightGrey;"| Chris Carey ||  style="background-color:LightGrey;"| Fluent Europe Ltd
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-08      
!  !! style="background-color:LightGrey;"|4-08      
| style="background-color:silver;"|[[Orifice/deflector flow]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Martin Sommerfeld || style="background-color:silver;"| Martin-Luther-Universitat Halle-Wittenberg
| style="background-color:LightGrey;"|[[Orifice/deflector flow]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Martin Sommerfeld || style="background-color:LightGrey;"| Martin-Luther-Universitat Halle-Wittenberg
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|4-09      
!  !! style="background-color:LightGrey;"|4-09      
| style="background-color:gold;"|[[Confined buoyant plume]] || style="background-color:gold;"| Isabelle Lavedrine, Darren Woolf || style="background-color:gold;"| Arup
| style="background-color:LightGrey;"|[[Confined buoyant plume]] || style="background-color:LightGrey;"| Isabelle Lavedrine, Darren Woolf || style="background-color:LightGrey;"| Arup
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-10      
!  !! style="background-color:LightGrey;"|4-10      
| style="background-color:silver;"|[[Natural convection in simple closed cavity]] || style="background-color:silver;"| Nicholas Waterson || style="background-color:silver;"| Mott MacDonald Ltd
| style="background-color:LightGrey;"|[[Natural convection in simple closed cavity]] || style="background-color:LightGrey;"| Nicholas Waterson || style="background-color:LightGrey;"| Mott MacDonald Ltd
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|4-11      
!  !! style="background-color:LightGrey;"|4-11      
| style="background-color:gold;"|[[Simple room flow]] || style="background-color:gold;"| Steve Gilham, Athena Scaperdas || style="background-color:gold;"| Atkins
| style="background-color:LightGrey;"|[[Simple room flow]] || style="background-color:LightGrey;"| Steve Gilham, Athena Scaperdas || style="background-color:LightGrey;"| Atkins
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:gold;"|4-13      
!  !! style="background-color:LightGrey;"|4-13      
| style="background-color:gold;"|[[Compression of vortex in cavity]] || style="background-color:gold;"| Afif Ahmed, Emma Briec || style="background-color:gold;"| RENAULT
| style="background-color:LightGrey;"|[[Compression of vortex in cavity]] || style="background-color:LightGrey;"| Afif Ahmed, Emma Briec || style="background-color:LightGrey;"| RENAULT
|- style="background-color:#AED7FF;"  
|- style="background-color:#AED7FF;"  
!  !! style="background-color:silver;"|4-14      
!  !! style="background-color:LightGrey;"|4-14      
| style="background-color:silver;"|[[Flow in pipes with sudden contraction]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Francesca Iudicello || style="background-color:silver;"| ESDU
| style="background-color:LightGrey;"|[[Flow in pipes with sudden contraction]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Francesca Iudicello || style="background-color:LightGrey;"| ESDU
|- style="background-color:#AED7FF;"
! !! style="background-color:LightGrey;"|4-16
| style="background-color:LightGrey;"|[[Flow in a 3D diffuser]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;"| Suad Jakirli&#x107;, Gisa  John-Puthenveettil || style="background-color:LightGrey"| Technische Universit&auml;t Darmstadt
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !! style="background-color:silver;"|4-16
! !! style="background-color:LightGrey;"|4-18
| style="background-color:silver;"|[[Flow in a 3D diffuser]] [[Image:Star_red.jpg]] || style="background-color:silver;"| Suad Jakirli&#x107;, Gisa  John-Puthenveettil || style="background-color:silver"| Technische Universit&auml;t Darmstadt
| style="background-color:LightGrey;"|[[Flow and heat transfer in a pin-fin array]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;" | Sofiane Benhamadouche||style="background-color:LightGrey;"| EDF
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !! style="background-color:silver;"|4-18
! !! style="background-color:LightGrey;"|4-19
| style="background-color:silver;"|[[Flow and heat transfer in a pin-fin array]] [[Image:Star_red.jpg]] || style="background-color:silver;" | Sofiane Benhamadouche||style="background-color:silver;"| EDF
| style="background-color:LightGrey;"|[[UFR_4-19|Converging-diverging transonic diffuser]]<!--[[Image:Star_red.jpg]]-->|| style="background-color:LightGrey;" | Z. Vlahostergios, K. Yakinthos ||style="background-color:LightGrey;"| Dept. of Mechanical Engineering, Aristotle University of Thessaloniki, Greece
|- style="background-color:#AED7FF;"
|- style="background-color:#AED7FF;"
! !! style="background-color:silver;"|4-19
! !! style="background-color:LightGrey;"|4-20
| style="background-color:silver;"|[[UFR_4-19|Converging-diverging transonic diffuser]] [[Image:Star_red.jpg]] || style="background-color:silver;" | Z. Vlahostergios, K. Yakinthos ||style="background-color:silver;"| Dept. of Mechanical Engineering, Aristotle University of Thessaloniki, Greece
| style="background-color:LightGrey;"|[[UFR_4-20|Mixing ventilation flow in an enclosure driven by a transitional wall jet]]|| style="background-color:LightGrey;" | T. Van Hooff, B. Blocken, G.J.F. van Heijst ||style="background-color:LightGrey;"| KU Leuven, Belgium and Eindhoven University of Technology, The Netherlands
|}
|}

Revision as of 11:05, 15 March 2018

Flow Type UFR number Underlying Flow Regime Contributor Organisation
Free Flows
1-01 Underexpanded jet Christopher Lea UK Health and Safety Laboratory
1-02 Blade tip and tip clearance vortex flow Michael Casey Sulzer Innotec AG
1-05 Jet in a Cross Flow Peter Storey ABB Alstom Power UK
1-06 Axisymmetric buoyant far-field plume Simon Gant UK Health & Safety Laboratory
1-07 Unsteady near-field plume Simon Gant UK Health & Safety Laboratory
Flows around Bodies
2-01 Flow behind a blunt trailing edge Charles Hirsch Vrije Universiteit Brussel
2-02 Flow past cylinder Wolfgang Rodi Universität Karlsruhe
2-03 Flow around oscillating airfoil Joanna Szmelter Cranfield University
2-04 Flow around (airfoils and) blades (subsonic) K. Papailiou NTUA
2-05 Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x10^6) Peter Voke University of Surrey
2-06 Flow around (airfoils and) blades (transonic) Jaromir Prihoda Czech Academy of Sciences
2-07 3D flow around blades Dirk Wilhelm ALSTOM Power (Switzerland) Ltd
2-10 Flow Around Finite-Height Circular Cylinder G. Palau-Salvador, W. Rodi Universidad Politecnica de Valencia, Karlsruhe Institute of Technology
2-11 High Reynolds Number Flow around Airfoil in Deep Stall Charles Mockett CFD Software GmbH and Technische Universitaet Berlin
Michael Strelets New Technologies and Services LLC (NTS) and St.-Petersburg State Polytechnic University
2-12 Turbulent Flow Past Two-Body Configurations A. Garbaruk, M. Shur and M. Strelets New Technologies and Services LLC (NTS) and St.-Petersburg State Polytechnic University
2-13 Fluid-structure interaction in turbulent flow past cylinder/plate configuration I (First swiveling mode) Michael Breuer Helmut-Schmidt Universität Hamburg
2-14 Fluid-structure interaction in turbulent flow past cylinder/plate configuration II (Second swiveling mode) Andreas Kalmbach, Guillaume De Nayer, Michael Breuer Helmut-Schmidt Universität Hamburg
2-15 Benchmark on the Aerodynamics of a Rectangular 5:1 Cylinder (BARC) Luca Bruno, Maria Vittoria Salvetti Politecnico di Torino, Università di Pisa
Semi-confined Flows
3-01 Boundary layer interacting with wakes under adverse pressure gradient - NLR 7301 high lift configuration Jan Vos CFS Engineering SA
3-03 2D Boundary layers with pressure gradients (A) Florian Menter AEA Technology
3-04 Laminar-turbulent boundary layer transition Andrzej Boguslawski Technical University of Czestochowa
3-05 Shock/boundary-layer interaction (on airplanes) Anthony Hutton Qinetiq
3-06 Natural and mixed convection boundary layers on vertical heated walls (A) André Latrobe CEA / DRN / Department de Thermohydraulique
3-07 Natural and mixed convection boundary layers on vertical heated walls (B) Mike Rabbitt British Energy
3-08 3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation Pietro Catalano CIRA
3-09 Impinging jet Jean-Paul Bonnet, Remi Manceau Université de Poitiers
3-10 The plane wall jet Jan Eriksson, Rolf Karlsson Vattenfall Utveckling AB
3-11 Pipe expansion (with heat transfer) Jeremy Noyce Magnox Electric
3-12 Stagnation point flow Beat Ribi MAN Turbomaschinen AG Schweiz
3-13 Flow over an isolated hill (without dispersion) Frederic Archambeau EDF - R&D Division
3-14 Flow over surface-mounted cube/rectangular obstacles Ian Castro University of Southampton
3-15 2D flow over backward facing step Arnau Duran CIMNE
3-18 2D Boundary layers with pressure gradients (B) Fred Mendonca Computational Dynamics Ltd
3-30 2D Periodic Hill Flow Christoph Rapp, Michael Breuer, Michael Manhart, Nikolaus Peller Technische Universität München, Helmut-Schmidt Universität Hamburg
3-31 Flow over curved backward-facing step Sylvain Lardeau CD-adapco, London, UK
3-32 Planar shock-wave boundary-layer interaction Jean-Paul Dussauge, P. Dupont, N. Sandham, E. Garnier Aix-Marseille Université and Centre National de la Recherche Scientifique UM 7343, University of Southampton, ONERA/DAAP
3-33 Turbulent flow past a wall-mounted hemisphere Jens Nikolas Wood, Guillaume De Nayer, Stephan Schmidt, Michael Breuer Helmut-Schmidt Universität Hamburg
3-34 Smooth wall separation and reattachment at high Reynolds numbers E. Guseva, M. Strelets Peter the Great St Petersburg Polytechnic University
Confined Flows
4-02 Confined coaxial swirling jets Stefan Hohmann MTU Aero Engines
4-03 Pipe flow - rotating Paolo Orlandi, Stefano Leonardi Universita di Roma 'La Sapienza'
4-04 Flow in a curved rectangular duct - non rotating Lewis Davenport Rolls-Royce Marine Power, Engineering & Technology Division
4-05 Curved passage flow Nouredine Hakimi NUMECA International
4-06 Swirling diffuser flow Chris Carey Fluent Europe Ltd
4-08 Orifice/deflector flow Martin Sommerfeld Martin-Luther-Universitat Halle-Wittenberg
4-09 Confined buoyant plume Isabelle Lavedrine, Darren Woolf Arup
4-10 Natural convection in simple closed cavity Nicholas Waterson Mott MacDonald Ltd
4-11 Simple room flow Steve Gilham, Athena Scaperdas Atkins
4-13 Compression of vortex in cavity Afif Ahmed, Emma Briec RENAULT
4-14 Flow in pipes with sudden contraction Francesca Iudicello ESDU
4-16 Flow in a 3D diffuser Suad Jakirlić, Gisa John-Puthenveettil Technische Universität Darmstadt
4-18 Flow and heat transfer in a pin-fin array Sofiane Benhamadouche EDF
4-19 Converging-diverging transonic diffuser Z. Vlahostergios, K. Yakinthos Dept. of Mechanical Engineering, Aristotle University of Thessaloniki, Greece
4-20 Mixing ventilation flow in an enclosure driven by a transitional wall jet T. Van Hooff, B. Blocken, G.J.F. van Heijst KU Leuven, Belgium and Eindhoven University of Technology, The Netherlands
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