Fluid dynamic boundary layer

Boundary layer thickness

Formation of a laminar boundary layer under the blue line on a flat surface (lower horizontal line). Re _x = v ₀ x / ν is here for each x smaller than Re _crit = 5 · 10 ⁵ .

${\ displaystyle \ delta \ colon \ quad v_ {x} (y = \ delta) = 0 {,} 99 \ cdot v_ {0}}$

In the case of a flat panel as in the picture, the boundary layer thickness increases with the root of the distance to the front edge of the panel:

${\ displaystyle \ delta \ simeq {\ sqrt {\ frac {\ nu \ cdot x} {v_ {0}}}} \ ,.}$

Other measures of the thickness of the boundary layer are

Speed ​​profile

${\ displaystyle v_ {x} (y) \ approx v_ {0} \ cdot \ left [1- \ left (1 - {\ frac {y} {\ delta}} \ right) ^ {2} \ right]}$

In the direction of flow, the thickness of the fluid dynamic boundary layer increases (blue curve in the figure). In pipes or channels, the boundary layers can grow together from the edges, so that the laminar flow is fully developed and the speed is a parabolic function of the distance from the wall.

Reynolds numbers

${\ displaystyle Re _ {\ delta}: = {\ frac {v_ {0} \ delta} {\ nu}}}$

educated. The Reynolds number

${\ displaystyle Re_ {l}: = {\ frac {v_ {0} l} {\ nu}}}$

increases with the length of the flow along the wall and it results: ${\ displaystyle l}$

${\ displaystyle {\ frac {\ delta} {l}} \ simeq {\ frac {1} {l}} {\ sqrt {\ frac {\ nu l} {v_ {0}}}} = {\ frac { 1} {\ sqrt {Re_ {l}}}} \ quad {\ text {and}} \ quad Re _ {\ delta} \ simeq {\ frac {v_ {0}} {\ nu}} {\ sqrt {\ frac {\ nu l} {v_ {0}}}} = {\ sqrt {Re_ {l}}} \ ,.}$

After a certain length of travel along a plate, the boundary layer becomes unstable and turns into a turbulent state, see below. This happens with the critical Reynolds number

${\ displaystyle Re _ {\ text {krit}} = \ left. {\ frac {v_ {0} l} {\ nu}} \ right | _ {\ text {krit}} = 5 \ cdot 10 ^ {5} \ ,.}$

The Reynolds number can be higher with a low-disturbance flow.

Wall shear stress

Due to the viscosity, the fluid transfers momentum to the wall, which is noticeable through the wall shear stress τ _w . In Newtonian fluids this is of the order of magnitude

${\ displaystyle \ tau _ {w} = \ eta \ left. {\ frac {\ partial v_ {x}} {\ partial y}} \ right | _ {y = 0} \ simeq \ eta {\ frac {v_ {0}} {\ delta}} \ simeq \ eta {\ frac {v_ {0}} {\ sqrt {\ frac {\ nu l} {v_ {0}}}}}} = {\ sqrt {\ frac { \ rho \ eta v_ {0} ^ {3}} {l}}}}$

The parameter η = ρ · ν is the dynamic viscosity (dimension ML ^–1 T ⁻¹ , unit Pa s ). If b is the width and l is the length of a plate with a flow around both sides, then the following applies to its shear stress resistance

${\ displaystyle W = 2bl \ tau _ {w} \ simeq b {\ sqrt {\ rho \ eta v_ {0} ^ {3} l}} \ ,.}$

Measure of time

Fluid elements that do not flow too close to the wall remain near the wall for a time proportional to . The following applies: ${\ displaystyle l / v_ {0}}$

${\ displaystyle \ delta \ simeq {\ sqrt {\ frac {\ nu l} {v_ {0}}}} \ simeq {\ sqrt {\ nu t}} \ ,.}$

This equation shows that the boundary layer thickness increases proportionally to the square root of the time at the beginning of the movement . ${\ displaystyle t}$

Boundary layer for large Reynolds numbers

Transition from laminar to turbulent boundary layer with a plate flow

At high Reynolds numbers, the boundary layer flow is turbulent ; H. within the boundary layer, the fluid elements can move in any direction. The thickness of the boundary layer is thicker than that of a laminar boundary layer, but remains very limited, see picture.

The main flow is said to be laminar. Then after a certain length of the flow along the wall, the flow becomes unstable. The Tollmien-Schlichting waves , named after their discoverers, are formed , whose wave front initially runs perpendicular to the direction of flow but parallel to the wall. Downstream these waves are superimposed with three-dimensional waves (indicated by helical lines), whereby the wave front adopts a sawtooth shape and characteristic Λ-vortices arise. These Λ-eddies disintegrate into turbulence spots (small helical lines), which eventually grow together to form a turbulent boundary layer. The turbulence improves the exchange of momentum between the fluid elements, which is why they have a higher mean wall-parallel velocity near the wall than in the laminar boundary layer. ${\ displaystyle {\ bar {v}} _ {x}}$

Viscose underlayer

Each wall has - even under a turbulent boundary layer - a viscous sublayer ( English viscous sublayer ), formerly laminar sublayer mentioned. Only when the roughness of the wall penetrates this sub-layer does it have an impact on the boundary layer, the frictional resistance and the flow. If, on the other hand, the sub-layer completely covers the roughness, the wall is hydraulically smooth .

In the viscous lower layer, the dimensionless coordinate formed with the wall shear stress velocity is smaller than one ${\ displaystyle u _ {\ tau}}$

${\ displaystyle y ^ {+}: = {\ frac {u _ {\ tau}} {\ nu}} \ cdot y <1}$

and the time-averaged speed in the thin sublayer increases approximately linearly with the distance to the wall:

${\ displaystyle {\ bar {v}} _ {x} = u _ {\ tau} \ cdot y ^ {+} = {\ frac {\ tau _ {w}} {\ eta}} \ cdot y \ ,. }$

Construction engineering

The boundary layer is important for the thermal insulation of buildings. Stone and glass windows have a high thermal conductivity compared to air. In fact, there is a boundary layer of air on the walls, which with λ = 5.8 * 10 ⁻⁵ insulates better than the masonry. The boundary layer can become thinner during a storm.

See also

• Boundary Layer Influence
• Stall
• Water wave

literature

• H. Oertel (ed.): Prandtl guide through fluid mechanics . Fundamentals and phenomena. 13th edition. Springer Vieweg, 2012, ISBN 978-3-8348-1918-5 . 
• H. Schlichting, K. Gersten: boundary layer theory . 9th edition. Springer Verlag, Berlin 1997, ISBN 3-540-55744-X . 
• Ernst Götsch: Aircraft technology . Motorbuchverlag, Stuttgart 2003, ISBN 3-613-02006-8
• OA Olejnik, VN Samokhin: Mathematical models in boundary layer theory. Chapman & Hall / CRC, Boca Raton 1999, ISBN 1-58488-015-5
• Joseph A. Schetz: Boundary layer analysis . Prentice-Hall, Englewood Cliffs 1993, ISBN 0-13-086885-X

Web links

Commons : Fluid dynamic boundary layer  - collection of images, videos and audio files

• Vortex visualization. IAG - Institute for Aerodynamics and Gas Dynamics, January 19, 2006, accessed on February 20, 2016 ( direct numerical simulation of the laminar-turbulent transition in a boundary layer). 

Individual evidence

1. ↑ Via fluid movement with very little friction . books.google.de. Retrieved May 7, 2011.
2. ↑ ^{a b c} Oertel (2012), p. 112
3. ↑ Oertel (2012), p. 117
4. ↑ Oertel (2012), p. 128
5. ^ Vogel, Helmut: "Problems from Physics", Springer - Verlag, 1977, ISBN 3-540-07876-2 , p. 87