UFR 3-36 Test Case: Difference between revisions

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\mathrm{x^*} &= x/H  \\
\mathrm{x^*} &= x/H  \\
\mathrm{y_{wall}^*} &= \frac{y-Y_A}{H}  \\
\mathrm{y_{wall}^*} &= \frac{y-Y_A}{H}  \\
\mathrm{C\_p} &= \frac{p-p_0}{\frac{1}{2} \rho U_{in}^2}  \\
\mathrm{C_p} &= \frac{p-p_ref}{\frac{1}{2} \rho U_{ref}^2}  \\
\mathrm{tau\_w} &= \frac{1}{Re_{in}} \left.\frac{\partial U}{\partial n}\right|_{y=0}  \\
\mathrm{tau\_w} &= \mu \left.\frac{\partial U}{\partial n}\right|_{y=y_{wall}}  \\
\mathrm{delta*}&= \int_{y_{\min}}^{\infty} \left( 1 - \frac{U- U_{\min}}{U_{in}-U_{\min}} \right) dy \\
\mathrm{delta*}&= \int_{y_{\min}}^{\infty} \left( 1 - \frac{U- U_{\min}}{U_{in}-U_{\min}} \right) dy \\
\mathrm{theta}&= \int_{y_{\min}}^{\infty} \frac{U- U_{\min}}{U_{in}-U_{\min}} \left( 1 - \frac{U- U_{\min}}{U_{in}-U_{\min}} \right) dy
\mathrm{theta}&= \int_{y_{\min}}^{\infty} \frac{U- U_{\min}}{U_{in}-U_{\min}} \left( 1 - \frac{U- U_{\min}}{U_{in}-U_{\min}} \right) dy

Revision as of 12:41, 22 November 2022

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 project, four different geometries with different separation behaviors were designed. Each configuration was computed with two different Reynolds numbers. The configuration described here presents an incipient separation test case 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. 1. The geometry comprises three main sections: Constant-Width Forebody section with the largest width , Contoured Boat-tail section with the contoured width and Constant-Width-Aftbody section with the smallest width . The width of the first section is fixed and the width of the last 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 width of each section is measured from a fixed arbitrary position for which .

Figure1 FlowDomain.png
Figure 1: 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. 1. The axial origin is set at the beginning of the Contoured Boat-tail section.

with , , and with .

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 body contour points are used in streamwise direction with a smaller spacing in the focus region. In the normal direction to the body wall points are used, of which are concentrated near the body wall region. The body wall-normal growth ratio is approximatively and the dimensionless distance from the wall is along the body wall for all meshes and simulation scenarios. For the inflow boundary situated 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. 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 far-field boundary condition situated from the viscous body wall. Symmetry boundary condition is used on both side planes of the 2D domain. 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 , statistic pressure at the reference position , statistic density at the reference position , statistic temperature at the reference position and the measured 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 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 grid made of quadrilateral elements with quadratic edges with a DG polynomial degree equal to (sixth order).

The flow problem is statistically two-dimensional since the turbulent flow is homogeneous in the span direction. The reference frame origin is located such that is the streamwise position of the step origin and the position in normal direction of flat plate region downstream the step. The inlet boundary is located at and the freestream condition is set. The outlet boundary is placed at and the outlet pressure condition is imposed. Above the solid wall, no-slip adiabatic condition is set between and , while shearless condition otherwise. At the top boundary freestream condition is imposed.

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 body surface:



  • Profiles




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

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