UFR |
Underlying Flow Regime |
Contributor |
Organisation
|
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 |
Fred Bloggs
|
Centre National de la Recherche Scientifique UM 7343, and Aix-Marseille Université
|