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- ...turbulent boundary layer transition]] || Andrzej Boguslawski || Technical University of Czestochowa | [[The plane wall jet]]<!--[[Image:Star_red.jpg]]-->|| Jan Eriksson, Rolf Karlsson4 KB (499 words) - 16:00, 17 February 2023
- ...ightGrey;"|[[Jet in a Cross Flow]] || style="background-color:LightGrey;"| Peter Storey || style="background-color:LightGrey;"| ABB Alstom Power UK ...tGrey;"| Joanna Szmelter || style="background-color:LightGrey;"| Cranfield University18 KB (1,983 words) - 15:58, 17 February 2023
- ...ion of the turbulent boundary layer from a smooth surface, reattachment of the separated shear layer, and relaxation of the reattached turbulent boundary layer farther7 KB (1,002 words) - 11:08, 15 March 2018
- Key physical features of the UFR in question are: separation of the turbulent boundary layer from turbulent structures in the separated shear layer, its reattachment to the plane wall, and further7 KB (1,059 words) - 11:10, 15 March 2018
- # <div id="15">'''Probst A''' (2016) Implementation and Assessment of the Synthetic-Eddy Method in an Unstructured Compressible Flow Solver. 6th Symp ...d="18">'''Rogers SE and Kwak D''' (1988) An Upwind Differencing Scheme for the Time-Accurate Incompressible Navier–Stokes Equations. AIAA Paper 1988-2588 KB (1,040 words) - 11:10, 15 March 2018
- In this section we first present major results of RANS computations of the considered flow and their comparison with the experimental data27 KB (3,997 words) - 11:09, 15 March 2018
- ==Brief Description of the Study Test Case== A 3D sketch of the experimental setup is shown in [[UFR_3-34_Test_Case#figure1|Fig. 1]].21 KB (3,094 words) - 11:09, 15 March 2018