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Boundary Layer Theory

Boundary Layer Theory. Steven A. Jones BIEN 501 Friday, April 11 2008. Momentum Balance. Learning Objectives: State the motivation for curvilinear coordinates. State the meanings of terms in the Transport Theorem

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Boundary Layer Theory

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  1. Boundary Layer Theory Steven A. Jones BIEN 501 Friday, April 11 2008 Louisiana Tech University Ruston, LA 71272

  2. Momentum Balance Learning Objectives: • State the motivation for curvilinear coordinates. • State the meanings of terms in the Transport Theorem • Differentiate between momentum as a property to be transported and velocity as the transporting agent. • Show the relationship between the total time derivative in the Transport Theorem and Newton’s second law. • Apply the Transport Theorem to a simple case (Poiseuille flow). • Identify the types of forces in fluid mechanics. • Explain the need for a shear stress model in fluid mechanics. The Stress Tensor. Appendix A.5 Show components of the stress tensor in Cartesian and cylindrical coordinates. Vectors and Geometry Louisiana Tech University Ruston, LA 71272

  3. Flow Over a Flat Plate y d – Boundary layer thickness x What can we say about this flow? Louisiana Tech University Ruston, LA 71272

  4. Flow Over a Body U0 y U d x Louisiana Tech University Ruston, LA 71272

  5. Continuity & Momentum Use 2-dimensional equations. In contrast to previous derivations, we do not say that terms are zero. We say that they are “small.” Louisiana Tech University Ruston, LA 71272

  6. Continuity Non-dimensionalize so that velocities and lengths are of order 1. Louisiana Tech University Ruston, LA 71272

  7. Exercise If: How do you non-dimensionalize: Louisiana Tech University Ruston, LA 71272

  8. x-Momentum Non-dimensionalize small If inertial terms are important with respect to viscous terms. Louisiana Tech University Ruston, LA 71272

  9. Characteristic Pressure Non-dimensionalize Louisiana Tech University Ruston, LA 71272

  10. y-momentum From y-momentum Small in comparison to Louisiana Tech University Ruston, LA 71272

  11. Characteristic Pressure From y-momentum P is not a function of y, so the pressure in the boundary layer is the pressure in the free stream, which can be determined from a potential flow solution. Take the derivative with respect to x to get something to plug into the x-momentum equation. Louisiana Tech University Ruston, LA 71272

  12. Final x-momentum, B.C.s Louisiana Tech University Ruston, LA 71272

  13. Flow Over a Flat Plate x x Velocity at large y does not depend on x. Louisiana Tech University Ruston, LA 71272

  14. Special Case: Flat Plate Use the stream function: Louisiana Tech University Ruston, LA 71272

  15. Special Case: Flat Plate Assume a similarity solution: Louisiana Tech University Ruston, LA 71272

  16. Special Case: Flat Plate Louisiana Tech University Ruston, LA 71272

  17. Special Case: Flat Plate Louisiana Tech University Ruston, LA 71272

  18. Final Differential Equation Or, more simply This equation is 3rd order and nonlinear. There is no closed form solution, but it can be solved numerically. Louisiana Tech University Ruston, LA 71272

  19. Final Differential Equation Remember that f is the stream function, so you must take derivatives to get velocity after you solve for f. x-velocity for flow over a flat plate. Louisiana Tech University Ruston, LA 71272

  20. Integral Momentum Boundary Instead of seeking an exact solution to the differential equation, we can integrate the equations for continuity and x-momentum. Louisiana Tech University Ruston, LA 71272

  21. Integral Momentum Boundary The terms in these equations have specific meanings. Wall shear stress Becomes zero because velocity becomes constant far from the boundary. Louisiana Tech University Ruston, LA 71272

  22. Integral Momentum Boundary The terms in these equations have specific meanings. Integrate by parts with Louisiana Tech University Ruston, LA 71272

  23. Integral Momentum Boundary Both velocities are zero at the wall. vx becomes Ufar from the boundary, and vy() is obtained from the integrated continuity equation. Louisiana Tech University Ruston, LA 71272

  24. Integral Momentum Boundary Because by Continuity: Louisiana Tech University Ruston, LA 71272

  25. Integral Momentum Boundary In summary: So: Louisiana Tech University Ruston, LA 71272

  26. Integral Momentum Boundary With: If we knew vx, we would be able to integrate for the wall shear stress. It turns out that the exact form of vx is not as important as one might think, and good results can be obtained with a form that looks reasonable and satisfies the boundary conditions. Louisiana Tech University Ruston, LA 71272

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