A computational model has been developed to study the mechanisms responsible for hot gas ingestion into the wheel-space cavity of a stationary high pressure turbine (HPT) cascade rig. Simulations were undertaken for the stationary rig described by Bunker et al. (2009, “An Investigation of Turbine Wheelspace Cooling Flow Interactions With a Transonic Hot Gas Path—Part I: Experimental Measurements,” ASME Paper No. GT2009-59237) in a companion paper. The rig consists of five vanes, a wheel-space cavity, and five cylinders that represent the blockage due to the leading edge of the rotor airfoils. The experimental program investigated two cylinder diameters and three clocking positions for a nominal coolant flow rate. Comparisons are made between the computed and measured flow-fields for the smaller of the two cylinders. It is demonstrated that the circumferential variation of pressure established by the vane wake and leading edge bow wave results in an unstable shear layer over the rim seal axial gap (trench) that causes hot gases to ingest for a nominal coolant flow. Steady-state computational fluid dynamics (CFD) simulations did not capture this effect and it was determined that an unsteady analysis was required in order to match the experimental data. Favorable agreement is noted between the time-averaged computed and measured pressure distributions in the circumferential direction both upstream and downstream of the trench, as well as within the trench itself. Furthermore, it is noted that time-averaged buffer cavity effectiveness agrees to within 5% of the experimental data for the cases studied. The validated CFD model is then used to simulate the effect of rotation by rotating the cylinders and disk at rotational rate that scales with a typical engine. A sliding mesh interface is utilized to communicate data between the stator and rotor domains. The stationary cases tend to ingest past the first angel-wing for a nominal coolant flow condition, whereas the effect of rotation helps pressurize the cavity and is responsible for preventing hot gas from entering the buffer cavity.

1.
Johnson
,
B. V.
,
Mack
,
G. J.
,
Paolillo
,
R. E.
, and
Daniels
,
W. A.
, 1994, “
Turbine Rim Seal Gas Path Flow Ingestion Mechanisms
,”
30th AIAA Joint Propulsion Conference
, Indianapolis, IN, Paper No. AIAA-94-2703.
2.
Abe
,
T.
,
Kikuchi
,
J.
, and
Takeuchi
,
H.
, 1979, “
An Investigation of Turbine Disk Cooling—Experimental Investigation and Observation of Hot Gas Flow Into a Wheelspace
,”
13th CIMAC Conference
, Vienna, Austria, Paper No. GT-30.
3.
Phadke
,
U. P.
, and
Owen
,
J. M.
, 1983, “
An Investigation of Ingress for an Air-Cooled Shrouded Rotating Disk System With Radial Clearance Seals
,”
ASME J. Eng. Power
0022-0825,
105
, pp.
178
183
.
4.
Chew
,
J. W.
,
Green
,
T.
, and
Turner
,
A. B.
, “
Rim Sealing of Rotor-Stator Wheelspaces in the Presence of External Flow
,” ASME Paper No. 94-GT-126.
5.
Green
,
T.
, and
Turner
,
A. B.
, 1992, “
Ingestion Into the Upstream Wheelspace of an Axial Turbine Stage
,” ASME Paper No. 92-GT-303.
6.
Bohn
,
D.
,
Rudzinski
,
B.
,
Sürken
,
N.
, and
Gärtner
,
W.
, 2000, “
Experimental and Numerical Investigation of the Influence of Rotor Blades on Hot Gas Ingestion Into the Upstream Cavity of an Axial Turbine Stage
,” ASME Paper No. 2000-GT-284.
7.
Gentilhomme
,
O.
,
Hills
,
N. J.
,
Turner
,
A. B.
, and
Chew
,
J. W.
, 2002, “
Measurement and Analysis of Ingestion Through a Turbine Rim Seal
,” ASME Paper No. GT-2002-30481.
8.
Hills
,
N. J.
,
Chew
,
J. W.
, and
Turner
,
A. B.
, 2002, “
Computational and Mathematical Modeling of Turbine Rim Seal Ingestion
,”
ASME J. Turbomach.
0889-504X,
124
, pp.
306
315
.
9.
Teramachi
,
K.
,
Hamabe
,
M.
,
Manabe
,
T.
, and
Yanagidani
,
N.
, 2003, “
Experimental and Numerical Investigation of Sealing Performance of Turbine Rim Seals
,”
ITGT2003
, Tokyo, TS-025.
10.
Cao
,
C.
,
Chew
,
J. W.
,
Millington
,
P. R.
, and
Hogg
,
S. I.
, 2003, “
Interaction of Rim Seal and Annulus Flows in an Axial Flow Turbine
,” ASME Paper No. GT2003-38368.
11.
Jakoby
,
R.
,
Zierer
,
T.
,
Lindblad
,
K.
,
Larsson
,
J.
,
de Vito
,
L.
,
Bohn
,
D. E.
,
Funcke
,
J.
, and
Decker
,
A.
, 2004, “
Numerical Simulation of the Unsteady Flow Field in an Axial Gas Turbine Rim Seal Configuration
,” ASME Paper No. GT2004-53829.
12.
Roy
,
R. P.
,
Zhou
,
D. W.
,
Ganesan
,
S.
,
Wang
,
C. -Z.
, and
Paolillo
,
R. E.
, 2007, “
The Flow Field and Main Gas Ingestion in a Rotor-Stator Cavity
,” ASME Paper No. GT2007-27671.
13.
Bunker
,
R. S.
,
Laskowski
,
G. M.
,
Kapetanovic
,
S.
,
Bailey
,
J. C.
,
Palafox
,
P.
,
Itzel
,
G. M.
,
Sullivan
,
M. A.
, and
Farrell
,
T. R.
, 2009, “
An Experimental and Computational Investigation of Turbine Wheelspace Cooling Flow Interaction With a Transonic Hot Gas Path
,” ASME Paper No. GT-2009-59237.
14.
Auvinen
,
M.
, 2005, “
Numerical Study of Gas Path Ingestion Into Turbine Disk Cavity in an Engine Environment
,” MS thesis, Helsinki University of Technology, Espoo, Finland.
15.
Mirzamoghadam
,
A. V.
,
Heitland
,
G.
,
Morris
,
M. C.
,
Smoke
,
J.
,
Malak
,
M.
, and
Howe
,
J.
, 2008, “
3D CFD Ingestion Evaluation of a High Pressure Turbine Rim Seal Disk Cavity
,” ASME Paper No. GT2008-50531.
16.
Ong
,
J. H. P.
,
Miller
,
R. J.
, and
Uchida
,
S.
, 2006, “
The Effect of Coolant Injection on the Endwall Flow of a High Pressure Turbine
,” ASME Paper No. GT2006–91060.
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