Conditions in the internal-air system of a high-pressure turbine stage are modeled using a rig comprising an outer preswirl chamber separated by a seal from an inner rotor-stator system. Preswirl nozzles in the stator supply the “blade-cooling” air, which leaves the system via holes in the rotor, and disk-cooling air enters at the center of the system and leaves through clearances in the peripheral seals. The experimental rig is instrumented with thermocouples, fluxmeters, pitot tubes, and pressure taps, enabling temperatures, heat fluxes, velocities, and pressures to be measured at a number of radial locations. For rotational Reynolds numbers of Reφ ≃ 1.2 × 106, the swirl ratio and the ratios of disk-cooling and blade-cooling flow rates are chosen to be representative of those found inside gas turbines. Measured radial distributions of velocity, temperature, and Nusselt number are compared with computations obtained from an axisymmetric elliptic solver, featuring a low-Reynolds-number k–ε turbulence model. For the inner rotor-stator system, the computed core temperatures and velocities are in good agreement with measured values, but the Nusselt numbers are underpredicted. For the outer preswirl chamber, it was possible to make comparisons between the measured and computed values for cooling-air temperatures but not for the Nusselt numbers. As expected, the temperature of the blade-cooling air decreases as the inlet swirl ratio increases, but the computed air temperatures are significantly lower than the measured ones. Overall, the results give valuable insight into some of the heat transfer characteristics of this complex system.

1.
Bunker
R. S.
,
Metzger
D. E.
, and
Wittig
S.
,
1992
a, “
Local Heat Transfer in Turbine Disk Cavities. Part I: Rotor and Stator Cooling With Hub Injection of Coolant
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
114
, pp.
211
220
.
2.
Bunker
R. S.
,
Metzger
D. E.
, and
Wittig
S.
,
1992
b, “
Local Heat Transfer in Turbine Disk Cavities. Part II: Rotor Cooling With Radial Injection of Coolant
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
114
, pp.
221
228
.
3.
Chen
J.-X.
,
Gan
X.
, and
Owen
J. M.
,
1996
, “
Heat Transfer in an Air-Cooled Rotor–Stator System
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
118
, pp.
444
451
.
4.
Chen, J.-X., Owen, J. M., and Wilson, M., 1993a, “Parallel-Computing Techniques Applied to Rotor–Stator Systems: Fluid Dynamics Computations,” Proc. 8th Intl. Conf. Numer. Meth. Laminar Turbulent Flow, Swansea, Pineridge Press, pp. 899–911.
5.
Chen, J.-X., Owen, J. M., and Wilson, M., 1993b, “Parallel-Computing Techniques Applied to Rotor–Stator Systems: Thermal Computations,” Proc. 8th Int. Conf. Numer. Meth. Thermal Problems, Swansea, Pineridge Press, pp. 1212–1226.
6.
Dibelius, G. H., and Heinen, M., 1990, “Heat Transfer From a Rotating Disc,” ASME Paper No. 90-GT-219.
7.
El-Oun
Z.
, and
Owen
J. M.
,
1989
, “
Pre-swirl Blade-Cooling Effectiveness in an Adiabatic Rotor–Stator System
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
111
, pp.
522
529
.
8.
Farthing, P. R., 1988, “The Effect of Geometry on Flow and Heat Transfer in a Rotating Cavity,” DPhil thesis, University of Sussex, United Kingdom.
9.
Iacovides, H., and Toumpanakis, P., 1993, “Turbulence Modelling of Flow in Axisymmetric Rotor–Stator Systems,” Proc. 5th Int. Symp. Refined Flow Modelling and Turbulence Measurements, Paris, Sept.
10.
Kilic
M.
,
Gan
X.
, and
Owen
J. M.
,
1994
, “
Transitional Flow Between Contrarotating Discs
,”
J. Fluid Mech.
, Vol.
281
, pp.
119
135
.
11.
Launder
B. E.
, and
Sharma
B. I.
,
1974
, “
Application of the Energy-Dissipation Model of Turbulence to the Calculation of Flow Near a Spinning Disc
,”
Letters in Heat and Mass Transfer
, Vol.
1
, pp.
131
138
.
12.
Long, C. A., 1991, “A Calibration Technique for Thermopile Heat-Flux Gauges,” Proc. 5th Int. Exhibition and Congress for Sensors and Systems Technology, Nuremberg.
13.
Meierhofer, B., and Franklin, C. J., 1981, “An Investigation of the Preswirled Cooling Airflow to a Turbine Disc by Measuring the Air Temperature in the Rotating Channels,” ASME Paper No. 81-GT-132.
14.
Morse
A. P.
,
1988
, “
Numerical Prediction of Turbulent Flow in Rotating Cavities
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
110
, pp.
202
215
.
15.
Northrop
A.
, and
Owen
J. M.
,
1988
, “
Heat Transfer Measurements in Rotating-Disc Systems. Part I: The Free Disc
,”
Int. J. Heat Fluid Flow
, Vol.
9
, pp.
19
26
.
16.
Ong
C. L.
, and
Owen
J. M.
,
1991
, “
Computation of the Flow and Heat Transfer Due to a Rotating Disc
,”
Int. J. Heat Fluid Flow
, Vol.
12
, pp.
106
115
.
17.
Owen, J. M., and Rogers, R. H., 1989, Flow and Heat Transfer in Rotating-Disc Systems, Vol. 1: Rotor–Stator Systems, Research Studies Press, Taunton; Wiley, New York.
18.
Phadke
U. P.
, and
Owen
J. M.
,
1988
, “
Aerodynamic Aspects of the Sealing of Gas Turbine Rotor–Stator Systems. Part I: The Behaviour of Simple Shrouded Rotating-Disc Systems in a Quiescent Environment
,”
Int. J. Heat Fluid Flow
, Vol.
9
, pp.
98
105
.
19.
Staub, F. W., 1992, “Rotor Cavity Flow and Heat Transfer With Inlet Swirl and Radial Outflows of Cooling Air,” ASME Paper No. 92-GT-378.
20.
Vaughan, C. M., Gilham, S., and Chew, J. W., 1989, “Numerical Solutions of Rotating Disc Flows Using a Non-linear Multigrid Algorithm,” Proc. 6th Intl. Conf. Numer. Meth. Laminar Turbulent Flow, Swansea, Pineridge Press, pp. 66–73.
21.
Wilson, M., Chen, J. X., Pilbrow, R. G., and Owen, J. M., 1994, “Computations of Flow and Heat Transfer in Pre-swirl Rotor–Stator Systems,” ICHMT Int. Symp. Turbulence, Heat and Mass Transfer, Lisbon, Aug.
22.
Wilson, M., and Owen, J. M., 1994, “Axisymmetric Computations of Flow and Heat Transfer in a Pre-swirl Rotor–Stator system,” Proc. 1st Int. Conf. Flow Interaction, Hong Kong, pp. 447–450.
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