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== Best Practice Advice ==
== Best Practice Advice ==
[Note that this page was copied verbatim from the HTML used in the original QNET web site.  It needs further work...]


The Knowledge Base contains:  
The Knowledge Base contains:  
Line 10: Line 8:


* A State-of-the-Art Review on each Thematic Area, written by a leading expert in the field.
* A State-of-the-Art Review on each Thematic Area, written by a leading expert in the field.


{| border="1"
{| border="1"
Line 21: Line 20:
| 1-04 || [[Channel flow with wall injection]] || [[Developing channel flow with mass injection through wall|4-07]]
| 1-04 || [[Channel flow with wall injection]] || [[Developing channel flow with mass injection through wall|4-07]]
|-
|-
| 1-05 || [[Ahmed body]]
| 1-05 || [[Ahmed body]] ||
|-
|-
| 1-08 || [[L1T2 3 element airfoil]] || [[Boundary layer interacting with wakes under adverse pressure gradient - NLR 7301 high lift configuration|3-01]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[Laminar-turbulent boundary layer transition|3-04]], [[Shock/boundary-layer interaction (on airplanes)|3-05]], [[2D Boundary layers with pressure gradients (B)|3-18]]
| 1-08 || [[L1T2 3 element airfoil]] || [[Boundary layer interacting with wakes under adverse pressure gradient - NLR 7301 high lift configuration|3-01]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[Laminar-turbulent boundary layer transition|3-04]], [[Shock/boundary-layer interaction (on airplanes)|3-05]], [[2D Boundary layers with pressure gradients (B)|3-18]]
|-
! rowspan="5" |[[State-of-the-Art Review: Combustion|AA2<br>State-of-the Art Review for Combustion]]
| 2-01 || [[Bluff body burner for CH4-HE turbulent combustion]] || [[Flow behind a blunt trailing edge|2-01]]
|-
| 2-03 || [[Gas burner controlled by variable density and/or counterflow]] ||
|-
| 2-05 || [[Airflow cyclic variations in IC engines]] || [[Compression of vortex in cavity|4-13]]
|-
| 2-06 || [[The confined TECFLAM swirling natural gas burner]] || [[Confined coaxial swirling jets|4-02]], [[Orifice/deflector flow|4-08]]
|-
| 2-07 || [[Confined double annular jet]] || [[Annular coaxial jets, flow and mixing|1-04]], [[Flow behind a blunt trailing edge|2-01]]
|-
! rowspan="7" |[[State-of-the-Art Review: Chemical, Process, Thermal and Nuclear Safety|AA3<br>State-of-the Art Review for Chemical, Process, Thermal Hydraulics and Nuclear Safety]]
| 3-01 || [[Buoyancy-opposed wall jet]] || [[The plane wall jet|3-10]], [[Confined buoyant plume|4-09]]
|-
| 3-02 || [[Induced flow in a T-junction]] || [[Pipe flow - rotating|4-03]]
|-
| 3-03 || [[Cyclone separator]] || [[Pipe flow - rotating|4-03]], [[Swirling diffuser flow |4-06]]
|-
| 3-05 || [[Buoyant gas air-mixing]] || [[Confined buoyant plume|4-09]]
|-
| 3-08 || [[Spray evaporation in turbulent flow]] || [[Pipe expansion (with heat transfer)|3-11]]
|-
| 3-10 || [[Combining/dividing flow in Y junction]] || [[Pipe expansion (with heat transfer)|3-11]], [[Pipe flow - rotating|4-03]]
|-
| 3-11 || [[Downward flow in a heated annulus]] || [[Natural and mixed convection boundary layers on vertical heated walls (A)|3-06]], [[Natural and mixed convection boundary layers on vertical heated walls (B)|3-07]]
|-
! rowspan="5" |[[State-of-the-Art Review: Civil Construction and HVAC|AA4<br>State-of-the Art Review for Civil Construction & HVAC]]
| 4-01 || [[Wind environment around an airport terminal building]] || [[Flow over surface-mounted cube/rectangular obstacles |3-14]]
|-
| 4-02 || [[Flow and Sediment Transport in a Laboratory Model of a stretch of the Elbe River]] ||
|-
| 4-03 || [[Air flows in an open plan air conditioned office]] || [[The plane wall jet |3-10]], [[Confined buoyant plume|4-09]], [[Simple room flow|4-11]]
|-
| 4-04 || [[Tunnel fire]] ||
|-
| 4-06 || [[Aerodynamic analysis of the great belt bridge]] || [[Flow past cylinder |2-02]]
|-
! rowspan="1" |[[State-of-the-Art Review: Environmental Flow|AA5<br>State-of-the Art Review for Environmental Flows]]
|5-05 || [[Boundary layer flow and dispersion over isolated hills and valleys]] || [[Flow over an isolated hill (without dispersion)|3-13]]
|-
! rowspan="9" |[[State-of-the-Art Review: Turbomachinery Internal Flow|AA6<br>State-of-the Art Review for Turbomachinery Internal Flows]]
| 6-02 || [[Low-speed centrifugal compressor]] || [[Blade tip and tip clearance vortex flow |1-02]], [[Flow around (airfoils and) blades (subsonic)|2-04]], [[Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x10^6)|2-05]], [[Flow around (airfoils and) blades (transonic)|2-06]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation|3-08]], [[The plane wall jet |3-10]], [[Stagnation point flow|3-12]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Flow in a curved rectangular duct - non rotating|4-04]], [[Curved passage flow|4-05]]
|-
| 6-03 || [[Annular compressor cascade without clearance]] || [[Flow around (airfoils and) blades (subsonic)|2-04]], [[Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x10^6)|2-05]], [[Flow around (airfoils and) blades (transonic)|2-06]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation|3-08]], [[Stagnation point flow|3-12]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Flow in a curved rectangular duct - non rotating|4-04]], [[Curved passage flow|4-05]]
|-
| 6-04 || [[Pump turbine]] || [[3D flow around blades|2-07]], [[Rotor/stator interaction|2-09]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[Stagnation point flow|3-12]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Pipe flow - rotating|4-03]], [[Flow in a curved rectangular duct - non rotating|4-04]], [[Curved passage flow|4-05]]
|-
| 6-05 || [[Annular compressor cascade with tip clearance]] || [[Blade tip and tip clearance vortex flow |1-02]], [[Flow around (airfoils and) blades (subsonic)|2-04]], [[Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x10^6)|2-05]], [[Flow around (airfoils and) blades (transonic)|2-06]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[Laminar-turbulent boundary layer transition|3-04]], [[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation|3-08]], [[The plane wall jet |3-10]], [[Stagnation point flow|3-12]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Bypass transition on a flat plate|3-19]], [[Flow in a curved rectangular duct - non rotating|4-0]], [[Curved passage flow|4-05]]
|-
| 6-06 || [[Gas Turbine nozzle cascade]] || [[2D Boundary layers with pressure gradients (A)|3-03]], [[Laminar-turbulent boundary layer transition|3-04]], [[Shock/boundary-layer interaction (on airplanes)|3-05]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Bypass transition on a flat plate|3-19]]
|-
| 6-07 || [[Draft tube]] || [[2D Boundary layers with pressure gradients (A)|3-03]], [[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation|3-08]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Flow in a curved rectangular duct - non rotating|4-04]], [[Curved passage flow|4-05]], [[Swirling diffuser flow |4-06]]
|-
| 6-08 || [[High speed centrifugal compressor]] || [[Flow around (airfoils and) blades (subsonic)|2-04]], [[Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x10^6)|2-05]], [[Flow around (airfoils and) blades (transonic)|2-06]], [[2D Boundary layers with pressure gradients (A)|3-03]], [[3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation|3-08]], [[The plane wall jet |3-10]], [[Stagnation point flow|3-12]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Flow in a curved rectangular duct - non rotating|4-04]], [[Curved passage flow|4-05]]
|-
| 6-10 || [[Axial compressor cascade]] || [[2D Boundary layers with pressure gradients (A)|3-03]], [[Laminar-turbulent boundary layer transition|3-04]], [[Stagnation point flow|3-12]], [[2D Boundary layers with pressure gradients (B)|3-18]], [[Bypass transition on a flat plate|3-19]]
|-
| 6-12 || [[Steam turbine rotor cascade]] || [[Flow around (airfoils and) blades (subsonic)|2-04]], [[Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x10^6)|2-05]], [[Flow around (airfoils and) blades (transonic)|2-06]], [[Laminar-turbulent boundary layer transition|3-04]], [[Shock/boundary-layer interaction (on airplanes)|3-05]], [[Bypass transition on a flat plate|3-19]]
|}
|}
<tr>
<td rowspan=5 class=tabtitle>
<a href="../TA2/AC2-00/TA2sotar.htm">AA2<br>
State-of-the Art<br>
Review for<br>
Combustion</a></td><td class=data height=30>2-01</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA2/AC2-01/A2-01adv.htm" Title="Contributed by:Partner-23  Universita di Firenze">Bluff body burner for CH4-HE turbulent combustion</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR2/UFR2-01/U2-01adv.htm" Title="Flow behind a blunt trailing edge">2-01</a.</td>
</tr>
<tr>
<td class=data height=30>2-03</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA2/AC2-03/A2-03adv.htm" Title="Contributed by:Partner-43  Technical University of Czestochowa">Gas burner controlled by variable density and/or counterflow</a></td><td class=sp>&nbsp;</td>
<td class=dataL>.</td>
</tr>
<tr>
<td class=data height=30>2-05</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA2/AC2-05/A2-05adv.htm" Title="Contributed by:Partner-06  RENAULT">Airflow cyclic variations in IC engines</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR4/UFR4-13/U4-13adv.htm" Title="Compression of vortex in cavity">4-13</a.</td>
</tr>
<tr>
<td class=data height=30>2-06</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA2/AC2-06/A2-06adv.htm" Title="Contributed by:Partner-17  MTU Aero Engines">The confined TECFLAM swirling natural gas burner</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR4/UFR4-02/U4-02adv.htm" Title="Confined coaxial swirling jets ">4-02</a>,
<a href="../UFR4/UFR4-08/U4-08adv.htm" Title="Orifice/deflector flow">4-08</a.</td>
</tr>
<tr>
<td class=data height=30>2-07</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA2/AC2-07/A2-07adv.htm" Title="Contributed by:Partner-01  Vrije Universiteit Brussel">Confined double annular jet</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR1/UFR1-04/U1-04adv.htm" Title="Annular coaxial jets, flow and mixing">1-04</a>,
<a href="../UFR2/UFR2-01/U2-01adv.htm" Title="Flow behind a blunt trailing edge">2-01</a.</td>
</tr>
<tr>
<td rowspan=7 class=tabtitle>
<a href="../TA3/AC3-00/TA3sotar.htm">AA3<br>
State-of-the Art<br>
Review for<br>
Chemical & Process, Thermal Hydraulics & Nuclear Safety</a></td><td class=data height=30>3-01</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-01/A3-01adv.htm" Title="Contributed by:Partner-38  Magnox Electric">Buoyancy-opposed wall jet</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-10/U3-10adv.htm" Title="The plane wall jet ">3-10</a>,
<a href="../UFR4/UFR4-09/U4-09adv.htm" Title="Confined buoyant plume">4-09</a.</td>
</tr>
<tr>
<td class=data height=30>3-02</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-02/A3-02adv.htm" Title="Contributed by:Partner-11  EDF - R&D Division">Induced flow in a T-junction</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR4/UFR4-03/U4-03adv.htm" Title="Pipe flow - rotating">4-03</a.</td>
</tr>
<tr>
<td class=data height=30>3-03</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-03/A3-03adv.htm" Title="Contributed by:Partner-32  Fluent Europe Ltd">Cyclone separator</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR4/UFR4-03/U4-03adv.htm" Title="Pipe flow - rotating">4-03</a>,
<a href="../UFR4/UFR4-06/U4-06adv.htm" Title="Swirling diffuser flow ">4-06</a.</td>
</tr>
<tr>
<td class=data height=30>3-05</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-05/A3-05adv.htm" Title="Contributed by:Partner-35  British Nuclear Fuels (BNFL)">Buoyant gas air-mixing</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR4/UFR4-09/U4-09adv.htm" Title="Confined buoyant plume">4-09</a.</td>
</tr>
<tr>
<td class=data height=30>3-08</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-08/A3-08adv.htm" Title="Contributed by:Partner-20  Martin-Luther-Universitat Halle-Wittenberg">Spray evaporation in turbulent flow</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-11/U3-11adv.htm" Title="Pipe expansion (with heat transfer)">3-11</a.</td>
</tr>
<tr>
<td class=data height=30>3-10</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-10/A3-10adv.htm" Title="Contributed by:Partner-31  Rolls-Royce Marine Power, Engineering & Technology Division">Combining/dividing flow in Y junction</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-11/U3-11adv.htm" Title="Pipe expansion (with heat transfer)">3-11</a>,
<a href="../UFR4/UFR4-03/U4-03adv.htm" Title="Pipe flow - rotating">4-03</a.</td>
</tr>
<tr>
<td class=data height=30>3-11</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA3/AC3-11/A3-11adv.htm" Title="Contributed by:Partner-45  British Energy">Downward flow in a heated annulus</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-06/U3-06adv.htm" Title="Natural and mixed convection boundary layers on vertical heated walls (A)">3-06</a>,
<a href="../UFR3/UFR3-07/U3-07adv.htm" Title="Natural and mixed convection boundary layers on vertical heated walls (B)">3-07</a.</td>
</tr>
<tr>
<td rowspan=5 class=tabtitle>
<a href="../TA4/AC4-00/TA4sotar.htm">AA4<br>
State-of-the Art<br>
Review for<br>
Civil Construction & HVAC</a></td><td class=data height=30>4-01</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA4/AC4-01/A4-01adv.htm" Title="Contributed by:Partner-02  Atkins">Wind environment around an airport terminal building</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-14/U3-14adv.htm" Title="Flow over surface-mounted cube/rectangular obstacles ">3-14</a.</td>
</tr>
<tr>
<td class=data height=30>4-02</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA4/AC4-02/A4-02adv.htm" Title="Contributed by:Partner-04  Universität Karlsruhe">Flow and Sediment Transport in a Laboratory Model of a stretch of the Elbe River</a></td><td class=sp>&nbsp;</td>
<td class=dataL>.</td>
</tr>
<tr>
<td class=data height=30>4-03</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA4/AC4-03/A4-03adv.htm" Title="Contributed by:Partner-33  Arup">Air flows in an open plan air conditioned office</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-10/U3-10adv.htm" Title="The plane wall jet ">3-10</a>,
<a href="../UFR4/UFR4-09/U4-09adv.htm" Title="Confined buoyant plume">4-09</a>,
<a href="../UFR4/UFR4-11/U4-11adv.htm" Title="Simple room flow">4-11</a.</td>
</tr>
<tr>
<td class=data height=30>4-04</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA4/AC4-04/A4-04adv.htm" Title="Contributed by:Partner-39  Mott MacDonald Ltd">Tunnel fire</a></td><td class=sp>&nbsp;</td>
<td class=dataL>.</td>
</tr>
<tr>
<td class=data height=30>4-06</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA4/AC4-06/A4-06adv.htm" Title="Contributed by:Partner-26  CIMNE">Aerodynamic analysis of the great belt bridge</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR2/UFR2-02/U2-02adv.htm" Title="Flow past cylinder ">2-02</a.</td>
</tr>
<tr>
<td rowspan=1 class=tabtitle>
<a href="../TA5/AC5-00/TA5sotar.htm">AA5<br>
State-of-the Art<br>
Review for<br>
Environmental Flows</a></td><td class=data height=30>5-05</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA5/AC5-05/A5-05adv.htm" Title="Contributed by:Partner-16  University of Southampton">Boundary layer flow and dispersion over isolated hills and valleys</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-13/U3-13adv.htm" Title="Flow over an isolated hill (without dispersion)">3-13</a.</td>
</tr>
<tr>
<td rowspan=9 class=tabtitle>
<a href="../TA6/AC6-00/TA6sotar.htm">AA6<br>
State-of-the Art<br>
Review for<br>
Turbomachinery Internal Flows</a></td><td class=data height=30>6-02</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-02/A6-02adv.htm" Title="Contributed by:Partner-10  NUMECA International">Low-speed centrifugal compressor</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR1/UFR1-02/U1-02adv.htm" Title="Blade tip and tip clearance vortex flow ">1-02</a>,
<a href="../UFR2/UFR2-04/U2-04adv.htm" Title="Flow around (airfoils and) blades (subsonic)">2-04</a>,
<a href="../UFR2/UFR2-05/U2-05adv.htm" Title="Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x106)">2-05</a>,
<a href="../UFR2/UFR2-06/U2-06adv.htm" Title="Flow around (airfoils and) blades (transonic)">2-06</a><br>
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a>,
<a href="../UFR3/UFR3-08/U3-08adv.htm" Title="3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation">3-08</a>,
<a href="../UFR3/UFR3-10/U3-10adv.htm" Title="The plane wall jet ">3-10</a>,
<a href="../UFR3/UFR3-12/U3-12adv.htm" Title="Stagnation point flow">3-12</a><br>
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a>,
<a href="../UFR4/UFR4-04/U4-04adv.htm" Title="Flow in a curved rectangular duct - non rotating">4-04</a>,
<a href="../UFR4/UFR4-05/U4-05adv.htm" Title="Curved passage flow">4-05</a.</td>
</tr>
<tr>
<td class=data height=30>6-03</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-03/A6-03adv.htm" Title="Contributed by:Partner-14  SNECMA Moteurs">Annular compressor cascade without clearance</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR2/UFR2-04/U2-04adv.htm" Title="Flow around (airfoils and) blades (subsonic)">2-04</a>,
<a href="../UFR2/UFR2-05/U2-05adv.htm" Title="Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x106)">2-05</a>,
<a href="../UFR2/UFR2-06/U2-06adv.htm" Title="Flow around (airfoils and) blades (transonic)">2-06</a>,
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a><br>
<a href="../UFR3/UFR3-08/U3-08adv.htm" Title="3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation">3-08</a>,
<a href="../UFR3/UFR3-12/U3-12adv.htm" Title="Stagnation point flow">3-12</a>,
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a>,
<a href="../UFR4/UFR4-04/U4-04adv.htm" Title="Flow in a curved rectangular duct - non rotating">4-04</a><br>
<a href="../UFR4/UFR4-05/U4-05adv.htm" Title="Curved passage flow">4-05</a.</td>
</tr>
<tr>
<td class=data height=30>6-04</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-04/A6-04adv.htm" Title="Contributed by:Partner-18  AEA Technology">Pump turbine</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR2/UFR2-07/U2-07adv.htm" Title="3D flow around blades">2-07</a>,
<a href="../UFR2/UFR2-09/U2-09adv.htm" Title="Rotor/stator interaction">2-09</a>,
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a>,
<a href="../UFR3/UFR3-12/U3-12adv.htm" Title="Stagnation point flow">3-12</a><br>
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a>,
<a href="../UFR4/UFR4-03/U4-03adv.htm" Title="Pipe flow - rotating">4-03</a>,
<a href="../UFR4/UFR4-04/U4-04adv.htm" Title="Flow in a curved rectangular duct - non rotating">4-04</a>,
<a href="../UFR4/UFR4-05/U4-05adv.htm" Title="Curved passage flow">4-05</a><b.</td>
</tr>
<tr>
<td class=data height=30>6-05</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-05/A6-05adv.htm" Title="Contributed by:Partner-22  NTUA">Annular compressor cascade with tip clearance</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR1/UFR1-02/U1-02adv.htm" Title="Blade tip and tip clearance vortex flow ">1-02</a>,
<a href="../UFR2/UFR2-04/U2-04adv.htm" Title="Flow around (airfoils and) blades (subsonic)">2-04</a>,
<a href="../UFR2/UFR2-05/U2-05adv.htm" Title="Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x106)">2-05</a>,
<a href="../UFR2/UFR2-06/U2-06adv.htm" Title="Flow around (airfoils and) blades (transonic)">2-06</a><br>
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a>,
<a href="../UFR3/UFR3-04/U3-04adv.htm" Title="Laminar-turbulent boundary layer transition">3-04</a>,
<a href="../UFR3/UFR3-08/U3-08adv.htm" Title="3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation">3-08</a>,
<a href="../UFR3/UFR3-10/U3-10adv.htm" Title="The plane wall jet ">3-10</a><br>
<a href="../UFR3/UFR3-12/U3-12adv.htm" Title="Stagnation point flow">3-12</a>,
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a>,
<a href="../UFR3/UFR3-19/U3-19adv.htm" Title="Bypass transition on a flat plate">3-19</a>,
<a href="../UFR4/UFR4-04/U4-04adv.htm" Title="Flow in a curved rectangular duct - non rotating">4-04</a><br>
<a href="../UFR4/UFR4-05/U4-05adv.htm" Title="Curved passage flow">4-05</a.</td>
</tr>
<tr>
<td class=data height=30>6-06</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-06/A6-06adv.htm" Title="Contributed by:Partner-23  Universita di Firenze">Gas Turbine nozzle cascade</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a>,
<a href="../UFR3/UFR3-04/U3-04adv.htm" Title="Laminar-turbulent boundary layer transition">3-04</a>,
<a href="../UFR3/UFR3-05/U3-05adv.htm" Title="Shock/boundary-layer interaction (on airplanes)">3-05</a>,
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a><br>
<a href="../UFR3/UFR3-19/U3-19adv.htm" Title="Bypass transition on a flat plate">3-19</a.</td>
</tr>
<tr>
<td class=data height=30>6-07</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-07/A6-07adv.htm" Title="Contributed by:Partner-27  Vattenfall Utveckling AB">Draft tube</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a>,
<a href="../UFR3/UFR3-08/U3-08adv.htm" Title="3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation">3-08</a>,
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a>,
<a href="../UFR4/UFR4-04/U4-04adv.htm" Title="Flow in a curved rectangular duct - non rotating">4-04</a><br>
<a href="../UFR4/UFR4-05/U4-05adv.htm" Title="Curved passage flow">4-05</a>,
<a href="../UFR4/UFR4-06/U4-06adv.htm" Title="Swirling diffuser flow ">4-06</a.</td>
</tr>
<tr>
<td class=data height=30>6-08</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-08/A6-08adv.htm" Title="Contributed by:Partner-28  MAN Turbomaschinen AG Schweiz and Partner-09  Sulzer Innotec AG">High speed centrifugal compressor</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR2/UFR2-04/U2-04adv.htm" Title="Flow around (airfoils and) blades (subsonic)">2-04</a>,
<a href="../UFR2/UFR2-05/U2-05adv.htm" Title="Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x106)">2-05</a>,
<a href="../UFR2/UFR2-06/U2-06adv.htm" Title="Flow around (airfoils and) blades (transonic)">2-06</a>,
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a><br>
<a href="../UFR3/UFR3-08/U3-08adv.htm" Title="3D boundary layers under various pressure gradients, including severe adverse pressure gradient causing separation">3-08</a>,
<a href="../UFR3/UFR3-10/U3-10adv.htm" Title="The plane wall jet ">3-10</a>,
<a href="../UFR3/UFR3-12/U3-12adv.htm" Title="Stagnation point flow">3-12</a>,
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a><br>
<a href="../UFR4/UFR4-04/U4-04adv.htm" Title="Flow in a curved rectangular duct - non rotating">4-04</a>,
<a href="../UFR4/UFR4-05/U4-05adv.htm" Title="Curved passage flow">4-05</a.</td>
</tr>
<tr>
<td class=data height=30>6-10</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-10/A6-10adv.htm" Title="Contributed by:Partner-34  Computational Dynamics Ltd">Axial compressor cascade</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR3/UFR3-03/U3-03adv.htm" Title="2D Boundary layers with pressure gradients (A)">3-03</a>,
<a href="../UFR3/UFR3-04/U3-04adv.htm" Title="Laminar-turbulent boundary layer transition">3-04</a>,
<a href="../UFR3/UFR3-12/U3-12adv.htm" Title="Stagnation point flow">3-12</a>,
<a href="../UFR3/UFR3-18/U3-18adv.htm" Title="2D Boundary layers with pressure gradients (B)">3-18</a><br>
<a href="../UFR3/UFR3-19/U3-19adv.htm" Title="Bypass transition on a flat plate">3-19</a.</td>
</tr>
<tr>
<td class=data height=30>6-12</td><td class=sp>&nbsp;</td>
<td class=dataL><a href="../TA6/AC6-12/A6-12adv.htm" Title="Contributed by:Partner-44  Czech Academy of Sciences">Steam turbine rotor cascade</a></td><td class=sp>&nbsp;</td>
<td class=dataL>
<a href="../UFR2/UFR2-04/U2-04adv.htm" Title="Flow around (airfoils and) blades (subsonic)">2-04</a>,
<a href="../UFR2/UFR2-05/U2-05adv.htm" Title="Flow around airfoils (and blades) A-airfoil (Ma=0.15, Re/m=2x106)">2-05</a>,
<a href="../UFR2/UFR2-06/U2-06adv.htm" Title="Flow around (airfoils and) blades (transonic)">2-06</a>,
<a href="../UFR3/UFR3-04/U3-04adv.htm" Title="Laminar-turbulent boundary layer transition">3-04</a><br>
<a href="../UFR3/UFR3-05/U3-05adv.htm" Title="Shock/boundary-layer interaction (on airplanes)">3-05</a>,
<a href="../UFR3/UFR3-19/U3-19adv.htm" Title="Bypass transition on a flat plate">3-19</a.</td>
</tr>
</table>

Latest revision as of 08:55, 4 June 2008

Best Practice Advice

The Knowledge Base contains:

  • Best Practice Advice for each of the Underlying Flow Regimes that distils the experience of the European community of specialists into guidelines for ensuring quality of CFD simulations;
  • Best Practice Advice for each of the Application Challenges based on existing knowledge, giving guidance to users attempting similar calculations to enable them to perform quality calculations and to interpret and deploy results with greater trust.
  • A State-of-the-Art Review on each Thematic Area, written by a leading expert in the field.


State of the Art Reviews AC Best Practice Advice for Application Challenges Best Practice Advice for Associated UFRs
AA1
State-of-the Art Review for External Aerodynamics
1-01 Aero-acoustic cavity 3-03, 3-18
1-02 RAE M2155 Wing 3-03, 3-05, 3-18
1-04 Channel flow with wall injection 4-07
1-05 Ahmed body
1-08 L1T2 3 element airfoil 3-01, 3-03, 3-04, 3-05, 3-18
AA2
State-of-the Art Review for Combustion
2-01 Bluff body burner for CH4-HE turbulent combustion 2-01
2-03 Gas burner controlled by variable density and/or counterflow
2-05 Airflow cyclic variations in IC engines 4-13
2-06 The confined TECFLAM swirling natural gas burner 4-02, 4-08
2-07 Confined double annular jet 1-04, 2-01
AA3
State-of-the Art Review for Chemical, Process, Thermal Hydraulics and Nuclear Safety
3-01 Buoyancy-opposed wall jet 3-10, 4-09
3-02 Induced flow in a T-junction 4-03
3-03 Cyclone separator 4-03, 4-06
3-05 Buoyant gas air-mixing 4-09
3-08 Spray evaporation in turbulent flow 3-11
3-10 Combining/dividing flow in Y junction 3-11, 4-03
3-11 Downward flow in a heated annulus 3-06, 3-07
AA4
State-of-the Art Review for Civil Construction & HVAC
4-01 Wind environment around an airport terminal building 3-14
4-02 Flow and Sediment Transport in a Laboratory Model of a stretch of the Elbe River
4-03 Air flows in an open plan air conditioned office 3-10, 4-09, 4-11
4-04 Tunnel fire
4-06 Aerodynamic analysis of the great belt bridge 2-02
AA5
State-of-the Art Review for Environmental Flows
5-05 Boundary layer flow and dispersion over isolated hills and valleys 3-13
AA6
State-of-the Art Review for Turbomachinery Internal Flows
6-02 Low-speed centrifugal compressor 1-02, 2-04, 2-05, 2-06, 3-03, 3-08, 3-10, 3-12, 3-18, 4-04, 4-05
6-03 Annular compressor cascade without clearance 2-04, 2-05, 2-06, 3-03, 3-08, 3-12, 3-18, 4-04, 4-05
6-04 Pump turbine 2-07, 2-09, 3-03, 3-12, 3-18, 4-03, 4-04, 4-05
6-05 Annular compressor cascade with tip clearance 1-02, 2-04, 2-05, 2-06, 3-03, 3-04, 3-08, 3-10, 3-12, 3-18, 3-19, 4-0, 4-05
6-06 Gas Turbine nozzle cascade 3-03, 3-04, 3-05, 3-18, 3-19
6-07 Draft tube 3-03, 3-08, 3-18, 4-04, 4-05, 4-06
6-08 High speed centrifugal compressor 2-04, 2-05, 2-06, 3-03, 3-08, 3-10, 3-12, 3-18, 4-04, 4-05
6-10 Axial compressor cascade 3-03, 3-04, 3-12, 3-18, 3-19
6-12 Steam turbine rotor cascade 2-04, 2-05, 2-06, 3-04, 3-05, 3-19