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Abstract

This article presents an experimental and computational study of the efficiency of an unshrouded transonic turbine. This research formed part of the EU Turbine Aero-Thermal External Flows II programme. The experiments were performed in the Oxford Turbine Research Facility (previously the Turbine Test Facility at QinetiQ, Farnborough). This facility is an engine scale, short duration, rotating transonic facility, in which M, Re, $T_{gas} / T_{wall}$ , and $N / \sqrt{T_{01}}$ are matched to engine conditions. For these experiments, the MT1 turbine stage was installed. Historically, turbine efficiency measurements are conducted in steady state adiabatic facilities. However, short-duration facilities allow simultaneous aerodynamic and heat transfer measurements with a significant reduction in cost. An efficiency measurement system was developed for this investigation, and this is briefly described. The system allows efficiency to be evaluated to bias and precision errors of approximately ±1.45 per cent and ±0.16 per cent, respectively, to 95 per cent confidence. The results of accurate area surveys of the turbine inlet and exit flows are presented and discussed. At the turbine exit, data were taken at two traverse planes, approximately 0.5 and 4.5 rotor axial chords downstream of the rotor. The turbine efficiency was experimentally evaluated based on the data at both planes, using a number of mixing models, which are discussed and compared. The experimental result of turbine efficiency is also compared to that estimated from a mean-line prediction. Full-stage steady and unsteady computational fluid dynamics of the experiment using the Rolls-Royce HYDRA code was conducted and is also presented. The predicted and measured rotor exit flow-fields are compared at both downstream traverse planes.

Keywords

high-pressure turbine efficiency measurement experimental computational CFD unshrouded transient shaft torque mass flow

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Hilditch, M. A., Fowler, A., Jones, T. V., Chana, K. S., Oldfield, M. L. G., Ainsworth, R. W., Hogg, S. I., Anderson, S. J., and Smith, G. C. Installation of a turbine stage in the Pyestock Isentropic Light Piston Facility. ASME paper no. 94-GT-277, 1994.

Beard

P. F.

Povey

Chana

K. S.

Turbine efficiency measurement systems for the QinetiQ turbine test facility. Trans ASME, J. Turbomachinery, 132(1), 011002–011002.

Keogh, R. C., Guenette, G. R., and Sommer, T. P. Aerodynamic performance measurements of a fully-scaled turbine in a short duration facility. ASME paper no. 2000-GT-486, 2000.

Porreca, L. and Dénos, R. Determination of the efficiency of a cooled turbine stage tested in a compression tube facility. In Proceedings of the 16th Sym-posium on Measuring techniques in transonic and supersonic flow on cascades and turbomachines, Cambridge, UK, 23–24 September 2002.

Yasa

Paniagua

Bussolin

Performance analysis of a transonic high-pressure turbine. Proc. IMechE, Part A: J. Power and Energy, 2007, 221, 767–778.

Atkins, N. R., Ainsworth, R. W., and Harvey, N. W. Aerodynamic performance measurement in a fully scaled transient turbine test facility. ASME paper no. GT2007-27142, 2007.

Casey, M. V. and Fesich, T. M. On the efficiency of compressors with diabatic flows. In Proceedings of the ASME TURBOEXPO 2009, Orlando, Florida, USA, 8–12 June 2009, paper no. GT2009-59015.

Chana, K. S. and Hilditch, M. A. A summary datum un-cooled measurements of the MT1 single stage high-pressure turbine in the DRA Pyestock Isen-tropic Light Piston Facility. IMT Area 3 Turbine Project AER2-CT92-0044 report (also DRA/AS/PTD/TR95046/1), 1995.

Chana, K. S. and Jones T. V. An investigation on turbine tip and shroud heat transfer. ASME paper no. GT-2002-30554, 2002.

10.

Atkins, N. A. and Ainsworth, R. W. Turbine aerodynamic performance measurement under non-adiabatic conditions. ASME paper no. GT2007-27143, 2007.

11.

Beard

P. F.

Povey

Direct shaft torque measurements in a transient turbine facility. J. Meas. Sci. Technol., 2010. 22(3), 035107–035107. (10pp). DOI: 10.1088/0957-0233/22/3/035107.

12.

Beard

P. F.

Povey

Ireland

P. T.

Mass flow rate measurement in a transonic test facility with temperature distortion and swirl. J. Flow Meas. Instrum., 2003. 19(5), 315–324. DOI: 10.1016/j.flowmeasinst.2008.03.004.

13.

Povey

Beard

P. F.

A novel experimental technique for accurate mass flow rate measurement. J. Flow Meas. Instrum., 2008. 19(5), 251–259. DOI: 10.1016/j.flowmeasinst.2007.11.005.

14.

Paniagua, G., Dénos, R., and Oropesa, M. Thermocouple probes for accurate temperature measurements in short duration facilities. In Proceedings of ASME Turbo Expo 2002: Power for Land, Sea, and Air, Amsterdam, The Netherlands, 3–6 June 2002, pp. 209–217.

15.

Lapworth, B. L. HYDRA-CFD: a framework for collaborative CFD development. In Proceedings of the International Conference on Scientific and engineering computation IC-SEC 2004, Singapore, 30 June–2 July 2004.

16.

Dzung

L. S.

Konstitentemittlewerte in der theorie der turbomaschinenfürkompressiblemedien. BBC-Mitt., 1971, 58, 485–492.

17.

Pianko, M. and Wazelt, F. Suitable averaging-techniques in non-uniform internal flows. AGARD Advisory report no. AGARD-AR-182, Propulsion and Energetic Panel Working Group 14, 1983.

18.

Main, A. D. J. Annular cascade turbine aerodynamics. PhD Thesis, Department of Engineering Science, University of Oxford, 1994.

19.

Kacker

S. C.

Okapuu

A mean line prediction method for axial flow turbine efficiency. Trans ASME, J. Engng Pwr, 1982, 104, 111–119.

20.

Smith

S. F.

A simple correlation of turbine efficiency. J. R. Aeronaut. Soc., 1965, 69, 467–470.

Experimental and computational fluid dynamics investigation of the efficiency of an unshrouded transonic high pressure turbine

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