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Abstract

Turbine aerothermal analysis is a key issue of the entire engine design as higher performance and longer component life must always be reached. For this purpose, a substantial effort is dedicated to aerothermal methods at Snecma-Moteur. This paper deals with the problem of heat transfer prediction on uncooled turbine blades. The main parameter investigated is the transition process, but consideration is also given to the turbulence model, effect of free stream turbulence on laminar boundary layer and mesh refinement. All the models are implemented in a three-dimensional Navier-Stokes code. Quasi-three-dimensional computations are used to evaluate all models, and then fully three-dimensional computations are performed. Aerothermal predictions are compared with static pressure and heat transfer measurements from the IACA and TATEF Brite-EuRam programmes carried out in the test facilities of DERA, Pyestock and the von Karman Institute.

Keywords

numerical simulation heat transfer high-pressure turbine blade transition models turbulence models

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References

Wilcox

D. C.

Simulation of transition with a two turbulence model. Am. Inst. Aeronaut. Astronaut. J., 1994, 32(2), 237–245.

Schmidt

R. C.

Patankar

S. V.

Simulating boundary layer transition with low Reynolds number ?-? turbulence models: Part 2. An approach to improving the predictions. J. Turbomachinery, January 1991, 113, 18–26.

Edwards

J. R.

Roy

C. J.

Blottner

F. G.

Hassan

A development of one-equation transition/turbulence models. AIAA paper 2000-0133, 2000.

Steelant

Dick

Calculation of transition in turbine cascades by conditioned Navier-Stokes equations. In Third European Conference on Turbomachinery, 1999.

Mayle

R. E.

The role of laminar-turbulent transition in gas turbine engines. J. Turbomachinery, October 1991, 113, 509–537.

Abu-Ghannam

B. J.

Shaw

Natural transition of boundary layerthe effect of turbulence, pressure gradient and flow history. J. Mech. Engng Sci., 1980, 22(5), 213–228.

Drela

MISES implementation of modified Abu-Ghanam/Shaw transition criterion. MIT Report Aero-Astro, November 1995.

Boyle

R. J.

Simon

F. F.

Mach number effects on turbine blade transition length prediction. ASME paper 98GT367, 1998.

Ramesh

O. N.

Hodson

H. P.

A new intermittency model incorporating the calming effect. In Third European Conference on Turbomachinery, 1999.

10.

Smith

M. C.

Kuethe

A. M.

Effects of turbulence on laminar skin friction and heat transfer. Phys. Fluids, 1966, 9(12), 2337–2344.

11.

Liamis

Lebret

Implementation of a low ?-? turbulence model in a 3D Navier-Stokes solver for turbomachinery flows. AIAA paper 95-2335, 1995.

12.

Hilditch

M. A.

Smith

G. C.

anderson

S. J.

Chana

K. S.

Jones

T. V.

Ainsworth

R. W.

Oldfield

M. L. G.

Unsteady measurements in an axial flow turbine. In AGARD Conference Proceedings 1996, p. 571.

13.

Sieverding

C. H.

Danos

Arts

Brouckaert

J.-F.

Paniagua

Experimental investigation of the unsteady rotor aerodynamics and heat transfer of a transonic turbine stage. VKI paper LS1998-02, 1998.

Aerothermal predictions with transition models for high-pressure turbine blades

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