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Effect of Pressure Gradient on the flow in a Boundary Layer

Effect of Pressure Gradient on the flow in a Boundary Layer. x. z. Boundary layer equation:. Pressure gradient is found from velocity field. Effect of Pressure Gradient on the flow in a Boundary Layer. x. z. At the wall, the boundary layer equation becomes:.

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Effect of Pressure Gradient on the flow in a Boundary Layer

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  1. Effect of Pressure Gradient on the flow in a Boundary Layer x z Boundary layer equation: Pressure gradient is found from velocity field

  2. Effect of Pressure Gradient on the flow in a Boundary Layer x z At the wall, the boundary layer equation becomes: In the accelerating part of the stream,

  3. Effect of Pressure Gradient on the flow in a Boundary Layer x z inflection point In the decelerating part of the stream,

  4. Effect of Pressure Gradient on the flow in a Boundary Layer x z Velocity distribution suggests that a ∂p/∂x> 0 contributes to thicken the boundary layer, as seen from continuity: Deceleration adds viscous effects to make the boundary layer grow. w is directed away from the wall – increase in boundary layer thickness with x

  5. Effect of Pressure Gradient on the flow in a Boundary Layer x z ∂p/∂x< 0 pressure gradient is “favorable” ∂p/∂x> 0 pressure gradient is “adverse” or “uphill” Rapid growth of boundary layer and large w field causes“flow separation”

  6. from Kundu’s book u = 0 Separation point = boundary between forward flow and backward flow near wall Drag caused by adverse pressure gradient = form drag Boundary layer equations only valid as far as the point of separation

  7. Analytical solutions of viscous flows can be found for Re << 1 Negligible inertial forces – Couette & Poiseuille flows

  8. Analytical solutions of viscous flows can be found for Re >> 1 Negligible viscous forces, except near a surface -- match irrotational outer (freestream) flow with boundary layer near surface

  9. For intermediate Re, more difficult analytical solutions – experiments and numerical solutions Low Re<< 1 1×103 < Re < 2×105 Re > 2×105

  10. www.soton.ac.uk/ses/outreach/greenpower/boundarylayers.html

  11. https://www.arl.psu.edu/capabilities/fsm.html Another example

  12. http://www.iafr.eu/TESI/5.htm#_Toc243930577

  13. von Karman Vortex Street http://upload.wikimedia.org/wikipedia/commons/b/b4/Vortex-street-animation.gif

  14. Re= 50 Re= 75 Re= 120

  15. http://alg.umbc.edu/usaq/archives/001854.html

  16. Aleutian Islands http://www.designyourway.net/blog/inspiration/extraordinary-satellite-photos-of-earth/

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