Longitudinal vortices in wind tunnel wall boundary layers

S. Mokhtari; P. Bradshaw

doi:10.1017/S0001924000019540

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Several workers have found evidence for the presence of longitudinal vortices in wind tunnel wall boundary layers near the centre line of each wall, although the only actual publication appears to be the reproduction of Bearman's work in Ref. 3. The phenomenon usually observed is shown in Fig. 1: the boundary layer is considerably thickened near the centre line. (This symmetrical and localised perturbation should be distinguished from the effect of non-uniformities in the wind tunnel screens which apparently also leads to longitudinal vortices, randomly spaced across the width of the working section). The hypothetical vortex pattern is also shown in Fig. 1: it arises because lateral pressure gradients in the wind tunnel contraction naturally deflect the slow-moving fluid in the boundary layer towards the centre line more strongly than the main ‘inviscid’ part of the flow, implying the generation of longitudinal vorticity: this is secondary flow of Prandtl's first kind.

References

1. Bearman, P. W. Unpublished work at National Physical Laboratory, 1969.Google Scholar

2. Welsh, M. C. Unpublished work at CSIRO, Melbourne, 1977.Google Scholar

3 Cebeci, T. and Bradshaw, P. Momentum Transfer in Boundary Layers. McGraw Mill Hemisphere, 1977.Google Scholar

4. Radshaw, P. The effect of wind tunnel screens on nominally two-dimensional boundary layers, J. Fluid Mech, 1965, 22, 679.Google Scholar

5. Bradshaw, P. and Bansod, P. The Flow in S-Shaped Ducts. Aero Quart, 1972, 23, 131.Google Scholar

6. Patel, V. C. Calibration of the Preston tube and limitations on its use in pressure gradients. J. Fluid Mech, 1965, 23, 185.Google Scholar

7. Mokhtari, S. Effect of wind tunnel contraction on a two-dimensional boundary layer. MSc project report, Department of Aeronautics, Imperial College, 1982.Google Scholar

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