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Aerodynamic Ground Effect: a case-study of the integration of CFD and experiments

Aerodynamic Ground Effect: a case-study of the integration of CFD and experiments Tracie Barber & Stephen Hall University of New South Wales, Sydney, Australia. Introduction . Ground Effect Issues causing discrepancies in results Boundary Conditions Deformable surface Viscous Effects

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Aerodynamic Ground Effect: a case-study of the integration of CFD and experiments

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  1. Aerodynamic Ground Effect: a case-study of the integration of CFD and experiments Tracie Barber & Stephen Hall University of New South Wales, Sydney, Australia

  2. Introduction • Ground Effect • Issues causing discrepancies in results • Boundary Conditions • Deformable surface • Viscous Effects • Moving Ground design and analysis • Continuing work

  3. Ground effect - applications

  4. WIG 40 20 0 400 0 -400 -800 -1000 kPa m/s Velocity Pressure

  5. Previous Research • Inviscid (ie panel methods) used extensively • Analytical methods also used (many assumptions, limitations) • Limited viscous CFD results • Inappropriate boundary conditions often used • Experimental results scarce / unreliable

  6. Current Work • Reynolds-Averaged Navier Stokes Equations (CFX & Fluent) • Higher order discretising schemes • RNG or Realizable k-e turbulence model, standard wall functions

  7. Test-cases

  8. Testcases: (2D) • NACA 4412 wing • Angles of attack: • 1.2O, 4O, 6.4O, 10O, 12O • Reynolds Number: • 8,200,000 • Clearances (h/c): • 0.05, 0.10, 0.50, 1.00, free air

  9. Boundary conditions IMAGE SLIP GROUND STATIONARY GROUND MOVING

  10. Results - velocity vectors SLIP IMAGE GROUND MOVING GROUND STATIONARY u=U

  11. Results - velocity contours

  12. PIV Analysis • Particle Image Velocimetry • Pairs of images allow particle movement to be determined • Nd-Yag laser, 532 nm, 100mJ/pulse • Particles of spherical latex (5mm) • Initial investigation considered effect of moving ground

  13. Moving Ground

  14. Moving Ground

  15. Moving Ground Stationary Ground

  16. Free Surface Effects • Most WIG craft operate over water • Lifting bodies produce a high pressure on their lower surface • “Does this pressure change the surface shape, and does this affect the aerodynamic characteristics of the body?”

  17. Free Surface Effects • Froude number • Reynolds number: • CFD model (VOF) overcomes this issue

  18. Max Surface Deformation Beneath Airfoil vs Froude Number

  19. Importance of Viscous Effects • Panel methods (inviscid) frequently used for ground effect • Real flow situations – will viscous effects greatly affect results?

  20. Results: Three-Dimensional • NACA 4412 wing, AR=6 • Angles of attack: • 1.2O, 4O, 6.4O, 10O • Reynolds Number: • 8,200,000 • Clearances (h/c): • 0.05, 0.10, 0.50, 1.00, free air

  21. Effect of Ground on Separation

  22. Effect of Ground on Wake h/c=1.00 h/c=0.05

  23. Moving Ground - wing

  24. PIV Results – Flow separation PIV tke CFD tke NACA 4412 wing at 12o, h/c=0.45, trailing edge region PIV tke CFD tke NACA 4412 wing at 12o, h/c=0.05, trailing edge region

  25. Moving Ground • Implementation of moving ground into 3ft x 4ft wind tunnel • Belt speed of 60m/s • Extensive CFD analysis to determine best configuration • Uniform velocity profile • Uniform turbulence profile

  26. Moving Ground - suspended Velocity Contours

  27. Moving Ground – suspended, leadup Velocity Contours

  28. Moving Ground, in line Velocity Contours

  29. Moving Ground, offset, leadup, suction Velocity Contours

  30. Moving Ground - turbulence 100 50 0

  31. Moving Ground – design & construction

  32. Stationary Ground Supersonic Ground Effect (Experimental) Stationary Ground Supersonic Ground Effect (CFD) Moving Ground Supersonic Ground Effect (CFD) Supersonic Ground Effect Shock Wave Validation Cases

  33. Real World Experiment CFD CFD GLUE Integration of CFD & Experiments

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