1. Advanced CFD Analysis of�Aerodynamics Using CFX Jorge Carregal Ferreira
Achim Holzwarth, Florian Menter
2. Outline CFX: Advanced CFD software
The company
The products
Turbulence Modells in CFX
Near wall treatment in CFX
Examples:
Duct with adverse pressure gradient
Airfoils
Heat transfer
3. CFX: Member of AEA Technology
4. CFX: Global Position CFD (Computational Fluid Dynamics) group of AEA Technology
Largest European CFD company
210 employees
8 main offices
Strong industrial presence
Growth rate approx. 25% per year
More than 1500 installed licenses
5. CFD-Analysis Generate geometry: fluid domain
Generate mesh: discrete representation of fluid domain
Solve Navier-Stokes Equiations
Analyse Results
Coupling: Optimisation, fluid-structure coupling, accoustic analysis, design improvements
6. Leading Technology in CFX-5 Easy to use
Pre-Processor CFX-Build based on MSC.Patran:
Unstructured hybrid grids
Coupled algebraic multigrid-solver (AMG): Accurate, robust and fast
Solution time scales linear with grid size
Excellent parallel performance
Grid adaptation
UNIX, NT, Linux
7. Leading Technology in CFX-5
Laminar and turbulent flows.
Stationary and transient solutions.
Large variaty of turbulence models.
Transport equations for additional scalars.
Multi-component and multi-phase fluids.
Coupling with solid heat conduction.
Solution depended mesh adaptation.
Linear scaling of solver with grid size.
Scalable parallel performance.
8. Preprocessing with CFX-Build
9. Turbulence Models in CFX-5 Release of the latest turbulence models
k-? Model Variants
k-? Model and BSL Model (Wilcox, Menter)
SST Model (Menter, Blending between k-? and k-?)
Reynolds Stress Models
Extended near-wall treatments
Scalable wall functions for k-?
Automatic near-wall treatment for k-? and SST
LES model (Smagorinski)
Documented validation cases on these models are available
Future: Improved LES and transition modelling
10. Problems of Standard k-? Model Two Problems:
Missing transport effects.
Too large length scales.
Result:
Reduced or omitted separation.
Very often: Too optimistic machine performance.
11. Standard k-? Model (Wilcox)
12. Standard k-? Model (Wilcox) Advantages:
Lower length scales near wall.
Robust sublayer formulation (low-Re).
Problem:
Free stream sensitivity.
Has not replaced k-? models.
13. k-? Model Free Stream Problem
14. k-? vs. k-? Formulation
15. Optimal Two Equation Model Combination of k-w and k-e model:
k-w model near the surface
k-e model for free shear flows (e equation is transformed to w)
Blending is performed automatically based on solution and distance from the surface.
This model is called “Baseline Model – BSL”
Combined with “Shear-Stress-Transport” limiter offers optimal boundary layer simulation capabilities.
BSL+Limiter gives SST model.
16. Diffuser Flow, 1
17. Diffuser Flow, 2
18. Wall Boundary Treatment
19. Scaling of Variables near Wall
20. Flat Plate: Velocity Profile
21. Flate Plate: Wall Friction
22. Low-Re k-? Model
23. k-? Automatic Switch
24. k-? Automatic Switch
25. Pipe Expansion with Heat Transfer
26. Pipe Expansion with Heat Transfer
27. Pipe Expansion with Heat Transfer
28. Pipe Expansion with Heat Transfer
29. Summary CFX: Advanced CFD software
Fast and robust solver technology
Powerful Pre- and Postprocessing tools
Leading Turbulence Modells
Robust near wall treatment
Allows for
Accurate solutions
Reliable Predictions
