1 / 69

Gas-kinetic schemes for flow computations

Gas-kinetic schemes for flow computations. Kun Xu Mathematics Department Hong Kong University of Science and Technology. Collaborators : Changqiu Jin, Meiliang Mao, Huazhong Tang, Chun-lin Tian. Acknowledgements : RGC6108/02E, 6116/03E,

yagil
Download Presentation

Gas-kinetic schemes for flow computations

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Gas-kinetic schemes for flow computations Kun Xu Mathematics Department Hong Kong University of Science and Technology

  2. Collaborators: Changqiu Jin, Meiliang Mao, Huazhong Tang, Chun-lin Tian Acknowledgements: RGC6108/02E, 6116/03E, 6102/04E,6210/05E

  3. Contents • Gas-kinetic BGK-NS flow solver • Navier-Stokes equations under gravitational field • Two component flow • MHD • Beyond Navier-Stokes equations

  4. FLUID MODELING Continuum Models Molecular Models Euler Deterministic Navier-Stokes Statistical Burnett Liouville MD Chapman-Enskog DSMC Boltzmann 0.1 10 Kn 0.001 Free moleculae Continuum Transition Slip flow

  5. Gas-kinetic BGK scheme for the Navier-Stokes equations fluxes

  6. Gas-kinetic Finite Volume Scheme • Based on the gas-kinetic BGK model, a time dependent gas distribution function is obtained under the following IC, • Update of conservative flow variables,

  7. BGK model: Equilibrium state: Collision time: A single temperature is assumed: To the Navier-Stokes order: in the smooth flow region !!!

  8. Relation between and macroscopic variables • Conservation constraint

  9. BGK flow solverIntegral solution of the BGK model

  10. Initial gas distribution function on both sides of a cell interface. The corresponding is where the non-equilibrium states have no contributions to conservative macroscopic variables,

  11. Equilibrium state

  12. Equilibrium state is determined by

  13. Where is determined by

  14. Numerical fluxes: • Update of flow variables:

  15. Double Cones Detached shock Attached shock

  16. Double-cone M=9.50 (RUN 28 in experiment) Mesh: 500x100

  17. Unified moving mesh method physical domain computational domain Unified coordinate system ( W.H.Hui, 1999) geometric conservation law

  18. The 2D BGK model under the transformation Particle velocity macroscopic velocity Grid velocity

  19. The computed paths - fluttering - - tumbling -

  20. computed experiment

  21. fluid force as functions of phase

  22. fluid force as functions of phase

  23. 3D cavity flow

  24. BGK model under gravitational field: Integral solution: where the trajectory is

  25. Integral solution: Gravitational potential

  26. X=0 for x<0 where for x>0

  27. Initial non-equilibrium state: Equilibrium state

  28. The gas distribution function at a cell interface: Flux with gravitational effect: Flux without gravitational effect (multi-dimensional):

  29. Steady state under gravitational potential N=500000 steps Diamond: with gravitational force term in flux Solid line: without G in flux

  30. Gas-kinetic scheme for multi-component flow . and have different

  31. Gas distribution function at a cell interface:

  32. Shock tube test:

  33. Sod test + =

  34. A Ms=1.22shock wave in air hits a helium cylindrical bubble

  35. Shock helium bubble interaction (Y.S. Lian and K. Xu, JCP 2000)

  36. Ideal Magnetohydrodynamics Equations in 1D

  37. Moments of a gas distribution function: Equilibrium state: The macroscopic flow variables are the moments of g. For example, Then, according to particle velocities, we can split flow variables as:

  38. With the definition of moments: We have Recursive relation:

  39. Therefore,

  40. Kinetic Flux vector splitting scheme (Croisille, Khanfir, and Ghanteur, 1995) free transport j+1/2

  41. Flux splitting for MHD equations:

  42. free transport Construction of equilibrium state: j collision , where j+1 j+1/2

  43. Equilibrium flux function: The BGK flux is a combination of non-equilibrium and equilibrium ones: (K. Xu, JCP159)

  44. 1D Brio-Wu test case: Left state: Right state: x-component velocity density solid lines: current BGK scheme dash-line: Roe-MHD solver

  45. y-component velocity By distribution shock Contact discontinuity +: BGK, o: Roe-MHD, *: KFVS

  46. Orszag-Tang MHD Turbulence: t=0.5 (a): density (b): gas pressure (c): magnetic pressure (d): kinetic energy 5th WENO

More Related