DOAP’s: Difference between revisions
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(New page: = Glossary = ==='''DOAPs: Design or Assessment Parameters'''=== These are used to judge the competency of CFD calculations. These are fully defined in each Application Challenge (e.g. th...) |
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These are used to judge the competency of CFD calculations. These are fully defined in each Application Challenge (e.g. the lift, drag and pitching moment of a wing; the pressure recovery in a diffuser; the species concentration at a given location downstream from a building, etc) | These are used to judge the competency of CFD calculations. These are fully defined in each Application Challenge (e.g. the lift, drag and pitching moment of a wing; the pressure recovery in a diffuser; the species concentration at a given location downstream from a building, etc) | ||
=== | ==='''AC: Application Challenge'''=== | ||
Examples of cutting-edge CFD applications in various industrial sectors. They are sufficiently complex to be realistic, and are cases for which both test data and example computations are available and can be compared. | Examples of cutting-edge CFD applications in various industrial sectors. They are sufficiently complex to be realistic, and are cases for which both test data and example computations are available and can be compared. | ||
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e.g Wind direction, angle of attack, aspect ratio, source rate etc. | e.g Wind direction, angle of attack, aspect ratio, source rate etc. | ||
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Latest revision as of 09:32, 3 September 2008
Glossary
DOAPs: Design or Assessment Parameters
These are used to judge the competency of CFD calculations. These are fully defined in each Application Challenge (e.g. the lift, drag and pitching moment of a wing; the pressure recovery in a diffuser; the species concentration at a given location downstream from a building, etc)
AC: Application Challenge
Examples of cutting-edge CFD applications in various industrial sectors. They are sufficiently complex to be realistic, and are cases for which both test data and example computations are available and can be compared.
UFR: Underlying Flow Regime
One of the elemental flows that form the building blocks of the full industrial Application Challenges
BPA: Best Practice Advice
GNDPs: Governing Non-Dimensional Parameters
e.g Reynolds, Mach, Grashof numbers
PDPs: Problem Definition Parameters
e.g Wind direction, angle of attack, aspect ratio, source rate etc.