UFR 3-36 Test Case

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HiFi-TURB-DLR rounded step

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Semi-confined flows

Underlying Flow Regime 3-36

Test Case Study

Brief Description of the Study Test Case

In the framework of the HiFi-TURB project, four different geometries with different boundary-layer properties were designed. Each configuration was computed with two different Reynolds numbers. The configuration described here presents a turbuluent boundary layer incipient to separation where the flow is on the brink of separation but does not separate with Reynolds number based on the step height . The geometry of this UFR alongside the mesh is shown in Fig. 2. The geometry comprises three main sections: Constant-height upstream section with the largest height , curved-step section with the contoured height and constant-height downstream section with the smallest height . The height of the upstream section is fixed while the height of the downstream section is modified to generate the desired APG. This modification is achieved through the variation of , which is the ratio of to . For incipient separation, . The height of each section is measured from a fixed arbitrary position for which m.

Figure1 FlowDomain.png
Figure 2: Flow Domain and grid of RANS simulations

The parametric geometry definition for the three relevant sections is given in [‌6] and is depicted in Fig. 2. The axial origin is set at the beginning of the curved-step section.

with , , and with and .

The different parameters with the corresponding values are listed in the table below:

Parameter
Value
Table 1: Geometry parameters

CFD Methods

Reynolds-Averaged Navier-Stokes computations

SSG/LRR- model

For the entire computational domain, a structured 2D mesh was created using Pointwise V18.2. Sensitivity studies were carried out on various meshes and the final mesh used in this UFR contains a total of points. Along the contour points are used in streamwise direction with a smaller spacing in the curved-step region. In the wall-normal direction points are used, of which are concentrated near the wall. The wall-normal growth ratio is approximatively and the dimensionless distance from the wall is along the wall for all meshes and simulation scenarios.

For the inflow boundary located at a reservoir-pressure inflow boundary condition is used. This boundary condition prescribes total pressure and total density. The inflow direction is by default perpendicular to the boundary face and a constant velocity is prescribed defined by the Mach number . The turbulent kinetic energy entering the flow domain is computed according to the defined value of the turbulent intensity, which is set to and the turbulent viscosity is defined using the ratio of eddy to molecular dynamic viscosity set to . Both values of the turbulent kinetic energy and the turbulent viscosity are required for defining reference values of the turbulent quantities used for the inflow boundary condition. For the outflow boundary at an exit-pressure outflow boundary condition is used. The exit pressure is adapted during the simulation to match the reference pressure at the coordinate point . The upper boundary is a permeable far-field Riemann boundary condition located from the viscous wall and computed via the approximate Riemann method of Roe. The SSG/LRR- computations were conducted with a 3D solver. Hence, a symmetry boundary condition is used on both side planes of the 2D domain and the solver is operated in a 2D manner (only one cell in spanwise direction). Reference parameters for are presented in Table 2.

Parameter
Value
Table 2: Boundary conditions

with the Mach number , the exit pressure , total inflow pressure , total inflow density , total inflow temperature , static pressure at the reference position , static density at the reference position , static temperature at the reference position and the static pressure at the reference position

Simulations were performed using the DLR in-house software TAU [‌8] where the seven-equation omega-based Differential Reynolds stress turbulence model SSG/LRR- [‌16] including the length scale correction [‌17] is already implemented. TAU is a Finite-Volume-based unstructured cell-centered on dual-grids code of second-order accuracy. For the computations performed here, the mean-flow and turbulence convective terms are discretized using second-order central schemes together with Matrix Dissipation. Low-Mach number preconditioning was applied and steady computations using a LU-SGS scheme were performed. All results presented in this report are based on fully converged simulations.

k- model

The RANS k- computations have been performed using the CFD code MIGALE. The solver uses the Discontinuous Galerkin (DG) method for the spatial discretization of the governing equations, here the compressible Reynolds-averaged Navier-Stokes equations coupled with the k- closure model [‌28]. The steady-state numerical solutions are sought by means of a Newton’s globalization strategy named pseudo-transient continuation [‌29]. Simulations have been performed on a 2D grid made of quadrilateral elements with quadratic edges (see Fig. 3) with a DG polynomial degree equal to (sixth order). Wall resolution in stream () and wall normal () directions at different streamwise locations is reported in the following

The wall resolution takes into account of the degree of the DG polynomial approximation. In particular, it is defined as

,

being the viscous length scale and the number of Degrees of Freedom per equation within the mesh element, here .

The flow problem is statistically two-dimensional since the turbulent flow is homogeneous in the span direction. As the k- computations were perfomed with a 3D solver, symmetry boundary condition is used on side planes of the two-dimensional domain and only one cell in spanwise direction is considered.

The computational domain of the RANS k- simulations is designed to match the value of the boundary layer thickness, , predicted by the uDNS at the checkpoint, cf. Lib:DNS_1-5. To this purpose, a precursor computation on a zero-pressure-gradient flat plate of length was carried out. To mimic a free-stream approaching the plate, the domain was extended upstream of the solid wall and a symmetry condition was set on the lower part of this extension. For the HiFi-TURB-DLR rounded step, the length of the no-slip wall upstream of the checkpoint was set equal to the distance from the leading edge of the precursor flat plate to the streamwise coordinate where , i.e., . Accordingly, the leading edge of the no-slip solid wall is located at . To mitigate spurious perturbations possibly originating at the outlet boundary, a “sacrificial buffer” is created downstream of the rounded step, i.e., at . In this region, a symmetry condition is set on the horizontal boundary and mesh coarsening is applied to reduce solution gradients. A near-wall detail of the domain together with the imposed boundary conditions is shown in Fig. 4.

At the inlet boundary, located at , the total pressure and temperature are set to the values and , respectively. The turbulent intensity at the domain entrance is and the ratio of eddy to molecular dynamic viscosity is equal to . The static pressure is set at outlet boundary placed at . The upper boundary is a permeable far-field Riemann boundary condition and is located from the viscous wall and computed via the exact Riemann solver.

UFR 3-36 Rounded Step k-omega grid.png
Figure 3: Computational grid above the rounded step for RANS k- model simulation
UFR 3-36 Rounded Step k-omega bottom boundary conditions.png
Figure 4: Bottom boundary for RANS k- model simulation

Data provided

Data provided here are from both SSG/LRR- as well as k- simulations. All quantities are non-dimensionalised using the step height and the freestream velocity :

  • WallQuantities.dat contains the following wall quantities extracted at the curved step viscous wall:



where and are local values, and are reference values at the reference position and is the magnitude of wall-tangential velocity at the boundary edge.

  • profiles.dat contains the velocity and Reynolds-Stress profiles in the vertical direction:
    for 37 different streamwise locations ( = -11, -10, -9, -8, -7, -6, -5, -4, -3, -2, -1, 0, 0.5, 0.75, 1, 1.25, 1.5, 1.75, 2, 2.25, 2.5, 2.75, 3, 3.25, 3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 11, 12, 13 and 14).




Contributed by: Erij Alaya and Cornelia Grabe — Deutsches Luft-und Raumfahrt Zentrum (DLR)

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