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Conservative FE-Discretisation of Navier-Stokes Equation: Overview & Interpretation

Understand the Navier-Stokes Equation and its application for fluid simulation, including interpretation of momentum, pressure, and viscosity terms. Learn about conservative FE-discretisation methods and compare Finite Difference (FD), Finite Volume (FV), and Finite Element (FE) approaches. Discover advantages, disadvantages, and importance of conservation laws in discretisation. Explore the concept of Conservative FE-Elements and grid point implementations for horizontal and vertical velocities.

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Conservative FE-Discretisation of Navier-Stokes Equation: Overview & Interpretation

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  1. A conservative FE-discretisation of the Navier-Stokes equation JASS 2005, St. Petersburg Thomas Satzger

  2. Overview • Navier-Stokes-Equation • Interpretation • Laws of conservation • Basic Ideas of FD, FE, FV • Conservative FE-discretisation of Navier-Stokes-Equation

  3. Navier-Stokes-Equation • The Navier-Stokes-Equation is mostly used for the numerical simulation of fluids. • Some examples are • Flow in pipes • Flow in rivers • Aerodynamics • Hydrodynamics

  4. Navier-Stokes-Equation The Navier-Stokes-Equation writes: Equation of momentum Continuity equation with Velocityfield Pressurefield Density Dynamic viscosity

  5. Navier-Stokes-Equation The interpretation of these terms are: Outer Forces Diffusion Pressure gradient Convection Derivative of velocity field

  6. Navier-Stokes-Equation • The corresponding for the components is: for the momentum equation, and for the continuity equation.

  7. Navier-Stokes-Equation • With the Einstein summation and the abbreviation we get: for the momentum equation, and for the continuity equation.

  8. Navier-Stokes-Equation • Now take a short look to the dimensions:

  9. Navier-Stokes-Equation - Interpretation • We see that the momentum equations handles with accelerations. If we rewrite the equation, we get: This means: Total acceleration is the sum of the partial accelerations.

  10. Navier-Stokes-Equation - Interpretation • Interpretation of the Convection fluidparticle Transport of kinetic energy by moving the fluid particle

  11. Navier-Stokes-Equation - Interpretation fluid particle • Interpretation of the pressure Gradient Acceleration of the fluid particle by pressure forces

  12. Navier-Stokes-Equation - Interpretation fluid particle • Interpretation of the Diffusion Distributing of kinetic Energy by friction

  13. Navier-Stokes-Equation - Interpretation for we get • Interpretation of the continuity equation • Conservation of mass in arbitrary domain this means: influx = out flux

  14. Navier-Stokes-Equation - Laws of conservation • Conservation of kinetic energy: • We must know that the kinetic energy doesn't increase, this means: • Proof:

  15. Navier-Stokes-Equation - Laws of conservation • With the momentum equation • it holds • Using the relations (proof with the continuity equation) • and

  16. Navier-Stokes-Equation - Laws of conservation • Additionally it holds • Therefore we get • Due to Greens identity we have

  17. Navier-Stokes-Equation - Laws of conservation • This means in total • We have also seen that the continuity equation is very important for energy conservation.

  18. Basic Ideas of FD, FE, FV • We can solve the Navier-Stokes-Equations only numerically. • Therefore we must discretise our domain. This means, we regard our Problem only at finite many points. • There are several methods to do it: • Finite Difference (FD) • One replace the differential operator with the difference operator, this mean you approximate by • or an similar expression.

  19. Basic Ideas of FD, FE, FV • Finite Volume (FV) • You divide the domain in disjoint subdomains • Rewrite the PDE by Gauß theorem • Couple the subdomains by the flux over the boundary • Finite Elements (FE) • You divide the domain in disjoint subdomains • Rewrite the PDE in an equivalent variational problem • The solution of the PDE is the solution of the variational problem

  20. Basic Ideas of FD, FE, FV • Comparison of FD, FE and FV Finite Difference Finite Volume Finite Element

  21. Basic Ideas of FD, FE, FV • Advantages and Disadvantages • Finite Difference: • + easy to programme • - no local mesh refinement • - only for simple geometries • Finite Volume: • + local mesh refinement • + also suitable for difficult geometries • Finite Element: • + local mesh refinement • + good for all geometries • BUT: • Conservation laws aren't always complied by the discretisation. This can lead to problems in stability of the solution.

  22. Conservative FE-Elements for the number of grid points for the horizontal velocity in the i-th grid point for the vertical velocity in the i-th grid point • We use a partially staggered grid for our discretisation. We write:

  23. Conservative FE-Elements • The FE-approximation is an element of an finite-dimensional function space with the basis • The approximation has the representation whereby

  24. Conservative FE-Elements • If we use a Nodal basis, this means • we can rewrite the approximation and and

  25. Conservative FE-Elements • Every approximation should have the following properties: • continuous • conservative • In the continuous case the continuity equation was very important for the conservation of mass and energy. • If the approximation complies the continuity pointwise in the whole area, e.g. , then the approximation preserves energy.

  26. Conservative FE-Elements • Now we search for a conservative interpolation for the velocities in a box. • We also assume that the velocities complies the discrete continuity equation.

  27. Conservative FE-Elements • Now we search for a conservative interpolation for the velocities in a box. • We also assume that the velocities complies the discrete continuity equation.

  28. Conservative FE-Elements • Now we search for a conservative interpolation for the velocities in a box. • We also assume that the velocities complies the discrete continuity equation.

  29. Conservative FE-Elements • Now we search for a conservative interpolation for the velocities in a box. • We also assume that the velocities complies the discrete continuity equation: (1)

  30. Conservative FE-Elements • The bilinear interpolation isn't conservative

  31. Conservative FE-Elements • The bilinear interpolation isn't conservative It is easy to show that

  32. Conservative FE-Elements • The bilinear interpolation isn't conservative Basis on the box

  33. Conservative FE-Elements • These basis function for the bilinear interpolation are called • Pagoden. • The picture shows the function on the whole support.

  34. Conservative FE-Elements • Now we are searching a interpolation of the velocities which complies the continuity equation on the box. • How can we construct such an interpolation?

  35. Conservative FE-Elements • Now we are searching a interpolation of the velocities which complies the continuity equation on the box. • How can we construct such an interpolation? Divide the box in four triangles.

  36. Conservative FE-Elements • Now we are searching a interpolation of the velocities which complies the continuity equation on the box. • How can we construct such an interpolation? Divide the box in four triangles. Make on every triangle an linear interpolation.

  37. Conservative FE-Elements • What's the right velocity in the middle?

  38. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  39. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  40. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  41. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  42. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  43. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  44. Conservative FE-Elements • What's the right velocity in the middle? We must have at every point in the box the following relations:

  45. Conservative FE-Elements • What's the right velocity in the middle?

  46. Conservative FE-Elements • What's the right velocity in the middle?

  47. Conservative FE-Elements • What's the right velocity in the middle?

  48. Conservative FE-Elements • What's the right velocity in the middle?

  49. Conservative FE-Elements • What's the right velocity in the middle?

  50. Conservative FE-Elements • What's the right velocity in the middle?

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