AC Index: Difference between revisions
Jump to navigation
Jump to search
No edit summary |
No edit summary |
||
Line 124: | Line 124: | ||
|- style="background-color:#AED7FF;" | |- style="background-color:#AED7FF;" | ||
![[Biomedical_Flows|Biomedical Flows]] !! !! !! !! | ![[Biomedical_Flows|Biomedical Flows]] !! !! !! !! | ||
|- style="background-color:#AED7FF;" | |- style="background-color:#AED7FF;" | ||
! !! style="background-color:LightGrey;"|7-01 | |||
| style="background-color:LightGrey;"|[[AC7-01|Airflow in the human upper airways]] || style="background-color:LightGrey;"| P. Koullapis ''et al.'' || style="background-color:LightGrey;"| University of Cyprus | |||
! !! style="background-color:LightGrey;"|7-02 | ! !! style="background-color:LightGrey;"|7-02 | ||
| style="background-color:LightGrey;"|[[AC7-02|Airflow in the human upper airways]] || style="background-color:LightGrey;"| P. Koullapis ''et al.'' || style="background-color:LightGrey;"| University of Cyprus | | style="background-color:LightGrey;"|[[AC7-02|Airflow in the human upper airways]] || style="background-color:LightGrey;"| P. Koullapis ''et al.'' || style="background-color:LightGrey;"| University of Cyprus | ||
|} | |} |
Revision as of 13:13, 22 June 2020
Application Area | AC number | Application Challenges | Contributor | Organisation | |||||
---|---|---|---|---|---|---|---|---|---|
External Aerodynamics | |||||||||
1-01 | Aero-acoustic cavity | Fred Mendonca | Computational Dynamics Ltd | ||||||
1-02 | RAE M2155 Wing | Pietro Catalano, Anthony Hutton | CIRA, Qinetiq | ||||||
1-05 | Ahmed body | Jean-Paul Bonnet, Remi Manceau | Université de Poitiers | ||||||
1-08 | L1T2 3 element airfoil | Jan Vos, Anthony Hutton | CFS Engineering SA, Qinetiq | ||||||
1-09 | Vortex breakdown above a delta wing with sharp leading edge | Johan Kok et al. | NLR | ||||||
Combustion | |||||||||
2-01 | Bluff body burner for CH4-HE turbulent combustion | Elisabetta Belardini | Universita di Firenze | ||||||
2-06 | The confined TECFLAM swirling natural gas burner | Stefan Hohmann | MTU Aero Engines | ||||||
2-07 | Confined double annular jet | Charles Hirsch | Vrije Universiteit Brussel | ||||||
2-08 | Premixed Methane-Air Swirl Burner (TECFLAM) | Guido Kuenne, Andreas Dreizler, Johannes Janicka | Darmstadt University of Technology | ||||||
2-09 | SANDIA Flame D | Andrzej Boguslawski, Artur Tyliszczak | Częstochowa University of Technology | ||||||
2-10 | Internal combustion engine flows for motored operation | Carl Philip Ding et al. | Technische Universität Darmstadt | ||||||
2-11 | Delft-Jet-in-Hot-Coflow (DJHC) burner | André Perpignan et al. | TU Delft | ||||||
2-12 | AC2-12 Turbulent separated inert and reactive flows over a triangular bluff body | D.A. Lysenko and M. Donskov | 3DMSimtek AS, Sandnes, Norway | ||||||
Chemical & Process, Thermal Hydraulics & Nuclear Safety | |||||||||
3-01 | Buoyancy-opposed wall jet | Jeremy Noyce | Magnox Electric | ||||||
3-02 | Induced flow in a T-junction | Frederic Archambeau | EDF - R&D Division | ||||||
3-03 | Cyclone separator | Chris Carey | Fluent Europe Ltd | ||||||
3-08 | Spray evaporation in turbulent flow | Martin Sommerfeld | Martin-Luther-Universitat Halle-Wittenberg | ||||||
3-10 | Combining/dividing flow in Y junction | Lewis Davenport | Rolls-Royce Marine Power, Engineering & Technology Division | ||||||
3-11 | Downward flow in a heated annulus | Mike Rabbitt | British Energy | ||||||
3-12 | Particle-laden swirling flow | Martin Sommerfeld | Martin-Luther-Universitat Halle-Wittenberg | ||||||
Civil Construction & HVAC | |||||||||
4-01 | Wind environment around an airport terminal building | Steve Gilham, Athena Scaperdas | Atkins | ||||||
4-02 | Flow and Sediment Transport in a Laboratory Model of a stretch of the Elbe River | Wolfgang Rodi | Universität Karlsruhe | ||||||
4-03 | Air flows in an open plan air conditioned office | Isabelle Lavedrine, Darren Woolf | Arup | ||||||
4-04 | Tunnel fire | Nicholas Waterson | Mott MacDonald Ltd | ||||||
Environmental Flows | |||||||||
5-05 | Boundary layer flow and dispersion over isolated hills and valleys | Ian Castro | University of Southampton | ||||||
Turbo-machinery Internal Flows | |||||||||
6-02 | Low-speed centrifugal compressor | Nouredine Hakimi | NUMECA International | ||||||
6-05 | Annular compressor cascade with tip clearance | K. Papailiou | NTUA | ||||||
6-06 | Gas Turbine nozzle cascade | Elisabetta Belardini, Francesco Martelli | Universita di Firenze | ||||||
6-07 | Draft tube | Jan Eriksson, Rolf Karlsson | Vattenfall Utveckling AB | ||||||
6-08 | High speed centrifugal compressor | Beat Ribi, Michael Casey | MAN Turbomaschinen AG Schweiz , Sulzer Innotec AG | ||||||
6-10 | Axial compressor cascade | Fred Mendonca | Computational Dynamics Ltd | ||||||
6-12 | Steam turbine rotor cascade | Jaromir Prihoda | Czech Academy of Sciences | ||||||
6-14 | Swirling flow in a conical diffuser generated with rotor-stator interaction | A. Javadi et al | Chalmers University of Technology, Göteborg, Sweden; | ||||||
6-15 | Vortex ropes in draft tube of a laboratory Kaplan hydro turbine at low load | A.V. Minakov et al. | Institute of Thermophysics SB RAS, Novosibirsk, Russia | ||||||
Biomedical Flows | |||||||||
7-01 | Airflow in the human upper airways | P. Koullapis et al. | University of Cyprus | 7-02 | Airflow in the human upper airways | P. Koullapis et al. | University of Cyprus |