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FLUID MECHANICS

FLUID MECHANICS. Lecture 7 Exact solutions. Scope of Lecture. To present solutions for a few representative laminar boundary layers where the boundary conditions enable exact analytical solutions to be obtained. Solving the boundary-layer equations. The boundary layer equations

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FLUID MECHANICS

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  1. FLUID MECHANICS Lecture 7 Exact solutions

  2. Scope of Lecture • To present solutions for a few representative laminar boundary layers where the boundary conditions enable exact analytical solutions to be obtained.

  3. Solving the boundary-layer equations • The boundary layer equations • Solution strategies: • Similarity solutions: assuming “self-similar” velocity profiles. The solutions are exact but such exact results can only be obtained in a limited number of cases. • Approximate solutions: e.g. using momentum integral equ’n with assumed velocity profile (e.g. 2nd Yr Fluids) • Numerical solutions: finite-volume; finite element,… • CFD adopts numerical solutions; similarity solutions useful for checking accuracy.

  4. SIMILARITY SOLUTIONS • Incompressible, isothermal laminar boundary layer over a flat plate at zero incidence (Blasius (1908)) • Partial differential equations for U and V with x and y as independent variables. • For a similarity solution to exist, we must be able to express the differential equations AND the boundary conditions in terms of a single dependent variable and a single independent variable.

  5. THE SIMILARITY VARIABLE U/U∞=F(h) U/U∞ • Condition of similarity • h is likely to be a function of xandy • Strategy: to replace x and yby h • Similarity variable • How to find dbefore solving the equation?

  6. THE SIMILARITY VARIABLE • To find the order of magnitude of d : From previous lecture • So • Similarity variable:

  7. NON-DIMENSIONAL STREAM FUNCTION • For incompressible 2D flows stream function y exists. • Strategy: To replace U and V with y • Define a non-dimensional stream functionfsuch thatfis a function of h only.

  8. NON-DIMENSIONAL STREAM FUNCTION • Find the order of magnitude of stream function y • Non-dimensional stream function

  9. SIMILARITY SOLUTIONS or Replace by derivatives WRT h • Convert the boundary layer equations Automatically satisfied by y Substituting so as to replace U, V by f Let

  10. Some details of analysis • Thus with: • we find: ; • So finally: • with b.c.’s

  11. SIMILARITY SOLUTIONS or • Substituting into the boundary layer equation 3rd order ordinary differential equation @ wall y =0, hence @ wall U=0, hence @ y= , U=U,hence

  12. VELOCITY PROFILES At Boundary layer thickness: The tabulated Blasius velocity profile can be found in many textbooks

  13. VELOCITY PROFILES V is much smaller than U.

  14. DISPLACEMENT AND MOMENTUN THICKNESS • Boundary layer thickness • Displacement thickness • Momentum thickness • d,d*, q all grow with x1/2 • d*/d=0.344, q/d =0.133

  15. DISPLACEMENT AND MOMENTUN THICKNESS d d* q • Typical distribution of d, d* and q U =10m/s, n=17x10-6 m2/s

  16. Other Useful Results • Shape factor: • Wall shear stress:

  17. Short Problem • The boundary layer over a thin aircraft wing can be treated as that over a flat plate. The speed of the aircraft is 100m/s and the chord length of the wing is 0.5m. At an altitude of 4000m, the density of air is 0.819kg/m3 and the kinematic viscosity is 20x10-6m2/s, Assuming the flow over the wing is 2D and incompressible, • Calculate the boundary-layer thickness at the trailing edge • Estimate the surface friction stress at the trailing edge • Will the boundary layer thickness and friction stress upstream be higher or lower compared to those at the trailing edge? • What will be the boundary-layer thickness and the surface friction stress at the same chord location if the speed of the aircraft is doubled?

  18. SOLUTIONS • The Reynolds number at x=0.5m: • The boundary layer thickness: • Friction stress at trailing edge of the wing

  19. SOLUTIONS • Will the boundary layer thickness and friction stress upstream higher or lower compared to those at the trailing edge? • d is smaller upstream as d is proportional to x1/2 • tw is higher upstream as d is thinner. • If the speed of the aircraft is doubled, Rex will be doubled since • d will be smaller as Re increases. • tw will be higher as the increase in U∞ has a greater effect than the increase in Rex.

  20. Plane stagnation flow • Flows with pressure gradients can be self-similar … but it has to be a pressure gradient compatible with self-similarity. See Schlichting and other “advanced” textbooks on fluid mechanics for examples. • Stagnation flow provides one such example where and potential flow) • Note by Euler equ’n. • The boundary layer equation thus becomes: • or • Here primes denote diff’n wrt

  21. Stagnation flow results • Note that the boundary layer has a constant thickness! • However, the mass within the boundary layer increases continuously since the velocity rises linearly with distance from the stagnation point. • Unlike the flat-plate boundary layer, the shear stress decreases continuously from the wall. • For this flow i.e. less than for the zero-pressure-gradient boundary layer.

  22. Asymptotic Suction Flow • Sometimes it may be desirable to withdraw fluid through the wall • If the suction is uniform a point is reached where the boundary layer no longer grows with distance downstream and no further change with x occurs. • Thus the continuity equation is just V/y= 0, i.e V= Vw • The x-momentum equation becomes: • …which is readily integrated to give • A question for you: What is the skin friction coefficient?

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