3 CFD Tools in EG3 Two primary codes –OVERFLOW – Navier-Stokes solver Requires chimera overset structured volume grids –CART3D – Euler solver Requires triangulated surface grids (geometry definition only) Automatic volume grids via sub-divided Cartesian grids Automation is important –CFD is becoming more accepted and relied upon as an analysis tool –The frequency and number of requested solutions is increasing EG3 has been asked to produce 150+ SSLV CFD solutions on a 33 million grid-point system for one of the return-to-flight tasks –Makes automation of the complete CFD process, including grid generation, essential SSLV elevon and body flap automation – animationanimation
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12 th International Meshing Roundtable Panel Discussion Darby
Vicker September 16, 2003 2 Background NASA/JSC/EG3 Applied
Aeroscience and Computational Fluid Dynamics (CFD) Branch Typical
uses of CFD in our branch include Aero databases stability and
trajectory analysis Calibration of flight instruments X-38 FADS
Separation models X-38/B-52 Verification of engineering analysis
Complete flow fields for debris analysis and flow feature
extraction SSLV Reynaldo GomezX-38/B-52 James GreathouseHigh
Fidelity X-38 Darby Vicker X-38 FADS 3 CFD Tools in EG3 Two primary
codes OVERFLOW Navier-Stokes solver Requires chimera overset
structured volume grids CART3D Euler solver Requires triangulated
surface grids (geometry definition only) Automatic volume grids via
sub-divided Cartesian grids Automation is important CFD is becoming
more accepted and relied upon as an analysis tool The frequency and
number of requested solutions is increasing EG3 has been asked to
produce 150+ SSLV CFD solutions on a 33 million grid-point system
for one of the return-to-flight tasks Makes automation of the
complete CFD process, including grid generation, essential SSLV
elevon and body flap automation animationanimation 4 Chimera Grid
Generation Structured grids that arbitrarily overlap Quick turn
around from grid generation to solutions Possible to grid complex
geometry with structured grids in a relatively short time Flow
solvers available are very efficient SSLV External Tank & Solid
Rocket Boosters 5 CAD Getting a quality representation of geometry
ready for grid generation is not trivial We receive geometry from
many CAD platforms (ProEngineer, CATIA, Unigraphics, etc.) For
complex geometry, there are often undesirable features Slivers,
gaps, highly warped or twisted surfaces, etc. Currently we rely on
3 rd party software to fix geometry problems and (usually)
translate to a neutral format 6 Mesh Quality Triangulated grid in
high curvature Wing leading edge example 7 Desirable Software
Features Batch mode operation Easily accessible feature information
Vertex location, arc length, surface area, etc. Grid diagnostics
Tabulated numbers and graphical indication of open edges, non-
manifold edges, etc. Improved (structured) surface grid creation
via extrusion Ease of use Robustness Variety of boundary conditions
Basic: float; periodic; splay; constant X, Y or Z Advanced: Follow
u or v of CAD patch; follow a curve; follow exact points on a
curve;
