Effects of Various Shaped Roughness Elements in Two-Dimensional High Reynolds Number Turbulent Boundary Layers

Bennington, Jeremy Lawrence

14 September 2004

Modeling the effects of surface roughness is an area of concern in many practical engineering applications. Many current roughness models to this point have involved the use of empirical 'constants' and equivalent sand grain roughness. These underdeveloped concepts have little direct relationship to realistic roughness and cannot predict accurately and consistently the flow characteristics for different roughness shapes. In order to aid in the development of turbulence models, the present research is centered around the experimental investigation of seven various shaped single roughness elements and their effects on turbulence quantities in a two-dimensional turbulent boundary layer. The elements under scrutiny are as follows: cone, cone with spatial variations equal to the smallest sublayer structure length scale, cone with spatial variations equal to 2.5 times the smallest sublayer structure length scale, Gaussian-shaped element, hemisphere, cube aligned perpendicular to the flow (cube at 90°), and a cube rotated 45° relative to the flow. The roughness element heights, k+, non-dimensionalized by the friction velocity (U_tau) of the approaching turbulent boundary layer, are 145, 145, 145, 145, 80, 98, and 98 respectively. Analysis of a three-dimensional fetch of the same Gaussian-shaped elements described previously was also undertaken. In order to analyze the complex flow fields, detailed measurements were obtained using a fine-measurement-volume (50 micron diameter) three-velocity component laser-Doppler velocimetry (LDV) system. The data reveals the formation of a horseshoe vortex in front of the element, which induces the downwash of higher momentum fluid toward the wall. This 'sweep' motion not only creates high Reynolds stresses (v^2, w^2, -uv) downstream of the element, but also leads to higher skin-friction drag. Triple products were also found to be very significant near the height of the element. These parameters are important in regards to the contribution of the production and diffusion of the turbulent kinetic energy in the flow. The 'peakiness' of the roughness element was found to have a direct correlation to the production of circulation, whereas the spatial smoothing does not have an immense effect on this parameter. The peaked elements were found to have a similar trend in the decay of circulation in the streamwise direction. These elements tend to show a decay proportional to (x/d)^-1.12, whereas the cube elements and the hemisphere do not have a common trend. A model equation is proposed for a drag correlation common to all roughness elements. This equation takes into account the viscous drag and pressure drag terms in the calculation of the actual drag due to the roughness elements presence in the boundary layer. The size, shape, frontal and wetted surface areas of the roughness elements are related to one another via this model equation. Flow drawings related to each element are presented which gives rise to a deeper understanding of the physics of the flow associated with each roughness element. / Master of Science

Isolated roughness elements

Distributed roughness

Near-wall flow structure

Drag correlation

Subsonic

Turbulent boundary layer

Turbulent kinetic energy

Laser-Doppler Velocimetry

Circulation decay

Conditions aux limites tridimensionnelles pour la simulation directe et aux grandes échelles des écoulements turbulents : modélisation de sous-maille pour la turbulence en région de proche paroi / Tridimensional Boundary Conditions for Direct and Large-Eddy Simulation of Turbulent Flows. Sub-Grid Scale Modeling for Near-Wall Region Turbulence

Lodato, Guido

05 December 2008

Le traitement des conditions aux limites et la modélisation fine des interactions de sous-maille ont été abordés dans cette thèse. La formulation caractéristique des conditions aux limites a été analysée et une nouvelle procédure 3D-NSCBC est proposée qui autorise la prise en compte de l’évolution de la vitesse et de la pression dans le plan des frontières, afin d’introduire le caractère tridimensionnel de l’écoulement dans les conditions limites. Des nouvelles formulations pour resoudre le couplage des ondes caractéristiques au niveau des arêtes et des coins ont été développées. Dans le cadre de la Simulation des Grandes Échelles, pour reproduire correctement la dynamique de la turbulence à la paroi et pour mieux prendre en compte l'anisotropie du tenseur des contraintes de sous-maille, un modèle structural fondé sur l'hypothèse de similarité est développé pour des écoulements modérément compressibles et validé sur la simulation d'un jet rond en impaction sur une paroi plane. / The treatment of boundary conditions and sub-grid scale interactions’ modeling, with particular attention to the asymptotic behavior near the wall, were addressed in this thesis. The characteristic formulation of boundary conditions has been analyzed and a novel procedure 3D-NSCBC is proposed, which, accounting for the evolution of velocity and pressure on the boundary planes, allows a better representation of the three-dimensional character of the flow at the boundary. New formulations to solve characteristic wave coupling on edges and corners are developed. Within the framework of the Large-Eddy Simulation, in order to give a correct reproduction of near-wall turbulence dynamics and in order to better account for the sub-grid scale stress tensor’s anisotropy, a structural model based on the similarity hypothesis has been developed for weakly compressible flows and validated on the simulation of a round jet impinging over a flat plane.

Conditions limites

Caractéristiques 3D

Simulation

Grandes échelles

Modèles Sous-Maille

Similarité-mixte

Asymptotique

Turbulence en paroi

Direct simulation

Large eddy simulation

Turbulent flows

Sub-grid scale modeling

Near-wall region turbulence