The Centroid-Deformation Decomposition for Buoyant Vortex Patch Motion.

The motion of a two-dimensional buoyant vortex patch, i. e., a vortex patch with a uniform density different from the uniform density of the surrounding fluid, is analyzed in terms of evolution equations for the motion of its centroid, deformation of its boundary and the strength distribution of a vortex sheet which is essential to enforce pressure continuity across the boundary. The equations for the centroid are derived by a linear momentum analysis and that for the sheet strength distribution by applying Euler’s equations on the boundary, while the boundary deformation is studied in the centroid-fixed frame. A complicated coupled set of equations is obtained which, to the best of our knowledge, has not been derived before. The evolution of the sheet strength distribution is obtained as an integral equation. The equations are also discussed in the limit of a patch of vanishing size or a buoyant point vortex

Experiments on Transition Detection Using chemical sublimation Technique and Hot-Film Gauges

The chemical sublimation technique using naphthalene was applied to detect boundary layer transition on a flat plate at low speeds. Comparison of location characterising the end of transition as detected by this technique with those mane employing velocity profile and transitional13; i ntermittency measurements showed satisfactory agreement. The above technique was also successfully applied in an exploratory test on the wing of the NAL light aircraft model at low speeds. To gain experience in the use of hot-films, a hot-film gauge was also calibrated in a zero pressure gradient turbulent boundary layer. These13; results are described in the Appendix