Environment-friendly microturbomachinery has its broad current and future applications in fuel cells, power generation, oil-free industrial blowers and compressors, small aero propulsions engines for missiles and small aircrafts, automotive turbo chargers, etc. Air foil bearings (AFBs) have been one of the popular subjects in recent years due to ever-growing interests in the environment-friendly oil-free turbomachinery. AFBs have many noticeable attractive features compared to conventional rigid-walled air/gas bearings such as improved damping and tolerance to minor shaft misalignment and external shocks. In addition, the low viscosity of air or gas allows very low power consumption even at high speeds. A turbine simulator mimicking 50 kW power generation gas turbine was designed. The turbine simulator can generate the same thermodynamic conditions and axial thrust load as the actual gas turbine. In this paper, the 3-D thermo-hydrodynamic (THD) model developed for single radial AFB was further extended to the turbine simulator configuration by extending the solution domain to the surrounding structures including two plenums, bearing sleeve, housing, and rotor exposed to the plenums. In addition, a computational fluid dynamic (CFD) model on the leading edge groove region was developed for better prediction of inlet thermal boundary conditions for the bearing. Several case studies are presented through computer simulations for hydrodynamically preloaded three-pad radial AFB in the hot section. It is found that both bearing and rotor should be provided with cooling air to maintain the temperature of both the rotor and top foil below 300 °C. It is also found that the higher thermal contact resistance between the rotor and hot impellers reduces the axial temperature gradient of the rotor. Dynamic performance of the bearing was evaluated using the linear perturbation method for operation at elevated temperature. The softening effect of the bump foil at elevated temperature results in a decrease of both stiffness and damping coefficients compared to the values at room temperature.

References

1.
Agnew
,
G. D.
,
Bozzolo
,
M.
,
Moritz
,
R. R.
, and
Berenyi
,
S.
, 2005,
“The Design and Integration of the Rolls-Royce Fuel Cell Systems 1MW SOFC,”
ASME Paper No. GT2005-69122.
2.
Mueller
,
F.
,
Gaynor
,
R.
,
Auld
,
A. E.
,
Brouwer
,
J.
,
Jabbari
,
F.
, and
Samuelsen
,
G. S.
, 2008, “
Synergistic Integration of a Gas Turbine and Solid Oxide Fuel Cell for Improved Transient Capability
,”
J. Power Sources
,
176
(
1
), pp.
229
239
.
3.
Tucker
,
D.
,
Lawson
,
R.
,
VanOsdol
,
J.
,
Kislear
,
J.
, and
Akinbobuyi
,
A.
, 2006,
“Examination of Ambient Pressure Effects on Hybrid Solid Oxide Fuel Cell Turbine System Operation Using Hardware Simulation,”
ASME Paper No. GT2006-91291.
4.
Veyo
,
S. E.
,
Shockling
,
L. A.
,
Dederer
,
J. T.
,
Gillett
,
J. E.
, and
Lundberg
,
W. L.
, 2002, “
Tubular Solid Oxide Fuel Cell/Gas Turbine Hybrid Cycle Power Systems: Status
,”
ASME J. Eng. Gas Turbines Power
,
124
(
4
), pp.
845
849
.
5.
Costamagna
,
P.
,
Magistri
,
L.
, and
Massardo
,
A. F.
, 2001, “
Design and Part-Load Performance of a Hybrid System Based on a Solid Oxide Fuel Cell Reactor and a Micro Gas Turbine
,”
J. Power Sources
,
96
(
2
), pp.
352
368
.
6.
Ku
,
C.-R.
, and
Heshmat
,
H.
, 1992, “
Compliant Foil Bearing Structural Stiffness Analysis: Part I – Theoretical Model Including Strip and Variable Bump Foil Geometry
,”
ASME J. Tribol.
,
114
(
2
), pp.
394
400
.
7.
Carpino
,
M.
, and
Talmage
,
G.
, 2006, “
Prediction of Rotor Dynamic Coefficients in Gas Lubricated Foil Journal Bearings With Corrugated Sub-Foils
,”
STLE Tribol. Trans.
,
49
(
3
), pp.
400
409
.
8.
San Andrés
,
L.
, and
Kim
,
T. H.
, 2007, “
Improvements to the Analysis of Gas Foil Bearings: Integration of Top Foil 1D and 2D Structural Models
,” ASME Paper No. GT2007-27249.
9.
Kim
,
D.
, 2007, “
Parametric Studies on Static and Dynamic Performance of Air Foil Bearings With Different Top Foil Geometries and Bump Stiffness Distributions
,”
ASME J. Tribol.
,
129
(
2
), pp.
354
364
.
10.
Kumar
,
M.
, and
Kim
,
D.
, 2008, “
Parametric Studies on Dynamic Performance of Hybrid Air Foil Bearings
,”
ASME J. Eng. Gas Turbines Power
,
130
(
6
), p.
062501
.
11.
Lee
,
D.
,
Kim
,
Y.
, and
Kim
,
T.
, 2009, “
The Dynamic Performance Analysis of Foil Journal Bearings Considering Coulomb Friction: Rotating Unbalance Response
,”
STLE Tribol. Trans.
,
52
(
2
), pp.
146
156
.
12.
Lee
,
D.
, and
Kim
,
D.
, 2010,
“Five Degrees of Freedom Nonlinear Rotor Dynamics Model of a Rigid Rotor Supported by Multiple Airfoil Bearings,”
Proceedings of the 8th IFToMM International Conference on Rotordynamics
,
Seoul, Korea
, September 12-15, Paper No. WeD1-2.
13.
Kim
,
D.
, and
Lee
,
D.
, 2010, “
Design of Three-Pad Hybrid Air Foil Bearing and Experimental Investigation on Static Performance at Zero Running Speed
,”
ASME J. Eng. Gas Turbine Power
,
132
(
12
), p.
122504
.
14.
Kim
,
D.
,
Lee
,
D.
,
Kim
,
Y. C.
, and
Ahn
,
K. Y.
, 2010,
“Comparison of Thermo-Hydrodynamic Characteristics of Airfoil Bearings With Different Top Foil Geometries,”
Proceedings of the 8th IFToMM International Conference on Rotordynamics
,
Seoul, Korea
, September 12-15, Paper No. WeD1-4.
15.
Kim
,
D.
, and
Lee
,
D.
, 2010,
“Design of Three-Pad Hybrid Air Foil Bearing and Experimental Investigation on Static Performance,”
Proceedings of 2010 STLE Annual Meeting and Exhibition
,
Las Vegas, Nevada, USA
, May 16-20.
16.
Kim
,
D.
, and
Park
,
S.
, 2009, “
Hydrostatic Air Foil Bearings: Analytical and Experimental Investigations
,”
Tribol. Int.
,
42
(
3
), pp.
413
425
.
17.
Kumar
,
M.
, and
Kim
,
D.
, 2010, “
Static Performance of Hydrostatic Air Bump Foil Bearing
,”
Tribol. Int.
,
43
(
4
), pp.
752
758
.
18.
DellaCorte
,
C.
,
Lukaszewicz
,
V.
,
Valco
,
M. J.
,
Radil
,
K. C.
, and
Heshmat
,
H.
, 2000, “
Performance and Durability of High Temperature Foil Air Bearings for Oil-Free Turbomachinery
,” NASA Technical Report, TM-2000-209187/ARL-TR-2202.
19.
Heshmat
,
H.
, 1994, “
Advancements in the Performance of Aerodynamic Foil Journal Bearings: High Speed and Load Capacity
,”
ASME J. Tribol.
,
116
(
2
), pp.
287
295
.
20.
Radil
,
K.
,
DellaCorte
,
C.
, and
Zeszotek
,
M.
, 2007, “
Thermal Management Techniques for Oil-Free Turbomachinery Systems
,”
STLE Tribol. Trans.
,
63
(
10
), pp.
319
327
.
21.
Howard
,
S. A.
, and
DellaCorte
,
C.
, 2001, “
Dynamic Stiffness and Damping Characteristics of a High-Temperature Air Foil Journal Bearing
,”
STLE Tribol. Trans.
,
44
(
4
), pp.
657
663
.
22.
Howard
,
S. A.
, and
DellaCorte
,
C.
, 2001, “
Steady-State Stiffness of Foil Air Journal Bearings at Elevated Temperatures
,”
STLE Tribol. Trans.
,
44
(
3
), pp.
489
493
.
23.
Heshmat
,
H.
,
Walton
,
J. F.
II
, and
Tomaszewski
,
M. J.
, 2005, “
Demonstration of a Turbojet Engine Using an Air Foil Bearing
,” ASME Paper No. GT2005-68404.
24.
Walton
,
I. I. J. F.
,
Heshmat
,
H.
, and
Tomaszewski
,
M. J.
, 2004, “
Testing of a Small Turbocharger/Turbojet Sized Simulator Rotor Supported on Foil Bearing
,” ASME Paper No. GT2004-53647.
25.
Heshmat
,
H.
,
Walton
,
J. F.
,
DellaCorte
,
C.
, and
Valco
,
M. J.
, 2000, “
Oil Free Turbocharger Demonstration Paves Way to Gas Turbine Engine Applications
,” ASME Paper No. 2000-GT-0620.
26.
DellaCorte
,
C.
, and
Edmonds
,
B. J.
, 1995, “
Preliminary Evaluation of PS300: A New Self-Lubricating High Temperature Composite Coating for Use to 800 °C
,” NASA, Cleveland, OH, NASA Technical Report TM-107056.
27.
Stanford
,
M. K.
,
Yanke
,
A. M.
, and
DellaCorte
,
C.
, 2004, “
Thermal Effects on a Low Cr Modification of PS304 Solid Lubricant Coating
,” NASA, Cleveland, OH, NASA Technical Report TM-2003-213111.
28.
Heshmat
,
H.
,
Hryniewicz
,
P.
,
Walton
,
J. F.
,
Willis
,
J. P.
,
Jahanmir
,
S.
, and
DellaCorte
,
C.
, 2005, “
Low-Friction Wear Resistant Coatings for High-Temperature Foil Bearings
,”
STLE Tribol. Int.
,
38
(
11-12
), pp.
1059
1075
.
29.
Lee
,
D.
, and
Kim
,
D.
, 2011, “
Design and Performance Prediction of Hybrid Air Foil Thrust Bearings
,”
ASME J. Eng. Gas Turbines Power
,
133
(
4
), p.
042501
.
30.
Dykas
,
B.
, and
Howard
,
S. A.
, 2004, “
Journal Design Considerations for Turbomachine Shafts Supported on Foil Air Bearings
,”
STLE Tribol. Trans.
,
47
(
3
), pp.
508
516
.
31.
Radil
,
K.
, and
Zeszotek
,
M.
, 2004, “
An Experimental Investigation Into the Temperature Profile of a Compliant Foil Air Bearing
,”
STLE Tribol. Trans.
,
47
(
4
), pp.
470
479
.
32.
Salei
,
M.
,
Swanson
,
E.
, and
Heshmat
,
H.
, 2001, “
Thermal Features of Compliant Foil Bearings---Theory and Experiments
,”
ASME J. Tribol.
,
123
(
3
), pp.
566
571
.
33.
Peng
,
Z. C.
, and
Khonsari
,
M.
, 2006, “
A Thermohydrodynamic Analysis of Foil Journal Bearings
,”
ASME J. Tribol.
,
128
(
3
), pp.
534
541
.
34.
San Andrés
,
L.
, and
Kim
,
T. H.
, 2009, “
Thermohydrodynamic Analysis of Bump Type Gas Foil Bearings: A Model Anchored to Test Data
,” ASME Paper No. GT2009-59919.
35.
Sim
,
K.
, and
Kim
,
D.
, 2008, “
Thermohydrodynamic Analysis of Compliant Flexure Pivot Tilting Pad Gas Bearings
,”
ASME J. Eng. Gas Turbines Power
,
130
(
3
), pp.
201
212
.
36.
Lee
,
D.
, and
Kim
,
D.
, 2010, “
Thermo-Hydrodynamic Analyses of Bump Air Foil Bearings With Detailed Thermal Model of Foil Structures and Rotor
,”
ASME J. Tribol.
,
132
(
2
), p.
021704
.
37.
Lee
,
D.
, and
Kim
,
D.
, 2011, “
Three-Dimensional Thermo-Hydrodynamic Analyses of Rayleigh Step Air Foil Thrust Bearing With Radially Arranged Bump Foils
,”
STLE Tribol. Trans.
,
54
(
3
), pp.
432
448
.
38.
Lee
,
D.
,
Kim
,
D.
, and
Sadashiva
,
R. P.
, 2011, “
Transient Thermal Behavior of Preloaded Three-Pad Foil Bearings: Modeling and Experiments
,”
ASME J. Tribol.
,
133
(
2
), p.
021703
.
39.
Timoshenko
,
S. P.
, and
Goodier
,
J. N.
, 1970,
Theory of Elasticity
,
McGraw-Hill
,
New York
, pp.
80
83
.
40.
Peng
,
J. P.
, and
Carpino
,
M.
, 1993, “
Calculation of Stiffness and Damping Coefficients for Elastically Supported Gas Foil Bearings
,”
ASME J. Tribol.
,
115
(
1
), pp.
20
27
.
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