Rotationally induced (RI) ingress is caused by the negative pressure (relative to the external air) inside the wheel-space of a gas turbine; this negative pressure, which is created by the rotating flow in the wheel-space, drives the ingestion of hot gas through the rim seals. Externally induced (EI) ingress is caused by the circumferential distribution of pressure created by the blades and vanes in the turbine annulus: Ingress occurs in those regions where the external pressure is higher than that in the wheel-space, and egress occurs where it is lower. Although EI ingress is the dominant mechanism for hot-gas ingestion in engines, there are some conditions in which RI ingress has an influence: This is referred to as combined ingress (CI). In Part I of this two-part paper, values of the sealing effectiveness (obtained using the incompressible orifice equations developed for EI ingress in an earlier paper) are compared with published experimental data and with the results obtained using 3D steady compressible computational fluid dynamics (CFD). Acceptable limits of the incompressible-flow assumption are quantified for the orifice model; For the CFD, even though the Mach number in the annulus reaches approximately 0.65, it is shown that the incompressible orifice equations are still valid. The results confirm that EI ingress is caused predominantly by the magnitude of the peak-to-trough circumferential difference of pressure in the annulus; the shape of the pressure distribution is of secondary importance for the prediction of ingress. A simple equation, derived from the orifice model, provides a very good correlation of the computed values of effectiveness. Using this correlation, it is possible to estimate the minimum sealing flow rate to prevent ingress without the need to know anything about the pressure distribution in the annulus; this makes the orifice model a powerful tool for rim-seal design.
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Research Papers
Prediction of Ingress Through Turbine Rim Seals—Part I: Externally Induced Ingress
J. Michael Owen,
J. Michael Owen
Department of Mechanical Engineering,
e-mail: ensjmo@bath.ac.uk
University of Bath
, Bath BA2 7AY, UK
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Kunyuan Zhou,
Kunyuan Zhou
School of Jet Propulsion,
Beihang University
, Beijing 100191, China
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Oliver Pountney,
Oliver Pountney
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UK
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Mike Wilson,
Mike Wilson
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UK
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Gary Lock
Gary Lock
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UK
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J. Michael Owen
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UKe-mail: ensjmo@bath.ac.uk
Kunyuan Zhou
School of Jet Propulsion,
Beihang University
, Beijing 100191, China
Oliver Pountney
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UK
Mike Wilson
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UK
Gary Lock
Department of Mechanical Engineering,
University of Bath
, Bath BA2 7AY, UKJ. Turbomach. May 2012, 134(3): 031012 (13 pages)
Published Online: July 15, 2011
Article history
Received:
July 14, 2010
Revised:
July 22, 2010
Online:
July 15, 2011
Published:
July 15, 2011
Connected Content
A companion article has been published:
Prediction of Ingress Through Turbine Rim Seals—Part II: Combined Ingress
Citation
Owen, J. M., Zhou, K., Pountney, O., Wilson, M., and Lock, G. (July 15, 2011). "Prediction of Ingress Through Turbine Rim Seals—Part I: Externally Induced Ingress." ASME. J. Turbomach. May 2012; 134(3): 031012. https://doi.org/10.1115/1.4003070
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