Computational prediction of flow around highly loaded compressor-cascade blades with non-linear eddy-viscosity models

1998 ◽  
Vol 19 (4) ◽  
pp. 307-319 ◽  
Author(s):  
W.L. Chen ◽  
F.S. Lien ◽  
M.A. Leschziner
Keyword(s):  
Eddy Viscosity ◽  
Computational Prediction ◽  
Compressor Cascade ◽  
Viscosity Models ◽  
Non Linear ◽  
Highly Loaded

Predictive Techniques for Turbulent Oscillatory Flows

1999 ◽  
Author(s):  
P. G. Tucker
Keyword(s):  
Eddy Viscosity ◽  
Oscillatory Flow ◽  
Turbulence Models ◽  
Reynolds Numbers ◽  
Intensity Measurements ◽  
Viscosity Models ◽  
Non Linear ◽  
Models Comparison ◽  
Normal Wall ◽  
Zonal Models

Abstract The prediction of turbulent oscillatory flow at around transitional Reynolds numbers is considered for an idealized electronics system. To assess the accuracy of turbulence models, comparison is made with measurements. A stochastic procedure is used to recover instantaneous velocity time traces from predictions. This procedure enables more direct comparison with turbulence intensity measurements which have not been filtered to remove the oscillatory flow component. Normal wall distances, required in some turbulence models, are evaluated using a modified Poisson equation based technique. A range of zero, one and two equation turbulence models are tested, including zonal and a non-linear eddy viscosity models. The non-linear and zonal models showed potential for accuracy improvements.

Assessment of turbulence model performance for transonic flow over an axisymmetric bump

2001 ◽  
Vol 105 (1043) ◽  
pp. 17-32 ◽  
Author(s):  
R. G. M. Hasan ◽  
J. J. McGuirk
Keyword(s):  
Velocity Profile ◽  
Eddy Viscosity ◽  
Computational Study ◽  
Model Performance ◽  
Turbulence Models ◽  
Research Programme ◽  
Wall Functions ◽  
Viscosity Models ◽  
Non Linear ◽  
Shock Location

Abstract A computational study has been performed to evaluate the predictive capabilities of some existing eddy-viscosity (both linear, LEVM, and non-linear, NLEVM) and Reynolds stress transport turbulence models (RSTM) by reference to a transonic shock-induced separated flow over a 10% axisymmetric bump. The calculations have been carried out during the course of a collaborative research programme including both UK universities and industry. The findings of the project demonstrate that improved results can be obtained for such flows by using more advanced turbulence models. For linear eddy-viscosity models, only the SST approach gave good predictions of shock location, recirculation size and pressure recovery, although this was accompanied by deficiencies in the prediction of post-shock velocity profile shape. Non-linear eddy-viscosity models, particularly at the cubic level, provided a more consistent level of agreement with experiments over the range of shock location, wall pressure and velocity profile parameters. Some improvement was also seen in the prediction of turbulence quantities, although only a move to an RSTM closure model reproduced the measured peak stress levels accurately. It was notable that the use of low-Re variants of the models (instead of wall functions) produced no significant improvement in predictions. There are, however, some shortcomings in all models, particularly in the development of flow after reattachment, which was always predicted to be too slow.

A turbulence model study of separated 3D jet/afterbody flow

2004 ◽  
Vol 108 (1079) ◽  
pp. 1-14 ◽  
Author(s):  
R. G. M. Hasan ◽  
J. J. McGuirk ◽  
D. D. Apsley ◽  
M. A. Leschziner
Keyword(s):  
Experimental Data ◽  
Mach Number ◽  
Turbulence Model ◽  
Eddy Viscosity ◽  
Three Dimensional ◽  
Model Performance ◽  
Turbulence Models ◽  
Research Programme ◽  
Viscosity Models ◽  
Non Linear

Three-dimensional RANS calculations and comparisons with experimental data are presented for subsonic and transonic flow past a non-axisymmetric (rectangular) nozzle/afterbody typical of those found in fast-jet aircraft. The full details of the geometry have been modelled, and the flow domain includes the internal nozzle flow and the jet exhaust plume. The calculations relate to two free-stream Mach numbers of 0-6 and 0-94 and have been performed during the course of a collaborative research programme involving a number of UK universities and industrial organisations. The close interaction between partners contributed greatly to the elimination of computational inconsistencies and to rational decisions on common grids and boundary conditions, based on a range of preliminary computations. The turbulence models used in the study include linear and non-linear eddy-viscosity models. For the lower Mach number case, the flow remains attached and all of the turbulence models yield satisfactory pressure predictions. However, for the higher Mach number, the flow over the afterbody is massively separated, and the effect of turbulence model performance is pronounced. It is observed that non-linear eddy-viscosity modelling provides improved shock capturing and demonstrates significant turbulence anisotropy. Among the linear eddy-viscosity models, the SST model predicts the best surface pressure distributions. The standard k -ε model gives reasonable results, but returns a shock location which is too far downstream and displays a delayed recovery. The flow field inside the jet nozzle is not influenced by turbulence modelling, highlighting the essentially inviscid nature of the flow in this region. However, the resolution of internal shock cells for identical grids is found to be dependent on the solution algorithm -specifically, whether it solves for pressure or density as a main dependent variable. Density-based time-marching schemes are found to return a better resolution of shock reflection. The paper also highlights the urgent need for more detailed experimental data in this type of flow.

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