Gas foil bearings (GFBs) have many noticeable advantages over the conventional rigid gas bearings, such as frictional damping of the compliance structure and tolerance to the rotor misalignment, so they have been successfully adopted as the key element that makes possible oil-free turbomachinery. As the adoption of the GFB increases, one of the critical elements for its successful implementation is thermal management. Even though heat generation inside the GFB is small due to the low viscosity of the lubricant, many researchers have reported that the system might fail without an appropriate cooling mechanism. The objective of the current research is to demonstrate the reliability of GFBs installed in the hot section of a micro-gas turbine (MGT). For the cooling of the GFBs, we designed a secondary flow passage and thermohydrodynamic (THD) analysis has been done for temperature prediction. In the analysis, the 3D THD model for the radial GFB extended to include the surrounding structure, such as the plenum, chamber, and the rotor in the solution domain by solving global mass and energy balance equations. In the MGT, the pressurized air discharged from the compressor wheel was used as the cooling air source, and it was injected into the plenum between two radial GFBs. We monitored the pressure and temperature of the cooling air along the secondary flow passage during the MGT operation. No thermal instability occurred up to the maximum operation speed of 43,000 rpm. The test results also showed that the pressure drop between the main reservoir and the plenum increases with an increasing operation speed, which indicated an increased cooling air flow into the plenum. The plenum and bearing sleeve temperature was maintained close to the cooling air source temperature for the entire speed due to a sufficient cooling air flow into the bearing. In addition, the direct injection of the cooling air from the main stream lowered the bearing sleeve temperature by 5–20 °C over the injection through the reservoirs. The predicted plenum and bearing sleeve temperatures with the developed THD model show good agreement with the test data.

References

1.
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
.
2.
Carpino
,
M.
, and
Talmage
,
G.
,
2003
, “
A Fully Coupled Finite Element Formulation for Elastically Supported Foil Journal Bearings
,”
STLE Tribol. Trans.
,
46
(
4
), pp.
560
565
.
3.
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.
4.
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
.
5.
Ku
,
C.-P. 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
.
6.
Lez
,
S. L.
,
Arghir
,
M.
, and
Frene
,
J.
,
2007
, “
A New Bump-Type Foil Bearing Structure Analytical Model
,”
ASME J. Eng. Gas Turbines Power
,
129
(
4
), pp.
1047
1057
.
7.
Lez
,
S. L.
,
Arghir
,
M.
, and
Frene
,
J.
,
2007
, “
Static and Dynamic Characterization of a Bump-Type Foil Bearing Structure
,”
ASME J. Tribol.
,
129
(
1
), pp.
75
83
.
8.
Lee
,
D.
,
Kim
,
Y.
, and
Kim
,
K.
,
2009
, “
The Dynamic Performance Analysis of Foil Journal Bearings Considering Coulomb Friction: Rotating Unbalance Response
,”
Tribol. Trans.
,
52
(
2
), pp.
146
156
.
9.
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
.
10.
Kim
,
D.
, and
Park
,
S.
,
2009
, “
Hydrostatic Air Foil Bearings: Analytical and Experimental Investigations
,”
Tribol. Int.
,
42
(
3
), pp.
413
425
.
11.
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 Turbines Power
,
132
(
12
), p.
122504
.
12.
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
.
13.
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
.
14.
Howard
,
S. A.
,
DellaCrote
,
C.
,
Valco
,
M. J.
,
Prahl
,
J. M.
, and
Heshmat
,
H.
,
2001
, “
Dynamic Stiffness and Damping Characteristics of a High Temperature Air Foil Journal Bearing
,”
STLE Tribol. Trans.
,
44
(
4
), pp.
657
663
.
15.
Kim
,
T.
,
Breedlove
,
A. W.
, and
San Andrés
,
L.
,
2009
, “
Characterization of a Foil Bearing Structure at Increasing Temperatures: Static Load and Dynamic Force Performance
,”
ASME J. Tribol.
,
131
(
4
), p.
041703
.
16.
San Andrés
,
L.
,
Ryu
,
K.
, and
Kim
,
T.
,
2011
, “
Identification of Structural Stiffness and Energy Dissipation Parameters in a Second Generation Foil Bearing: Effect of Shaft Temperature
,”
ASME J. Eng. Gas Turbines Power
,
133
(
3
), p.
032501
.
17.
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
.
18.
Peng
,
Z. C.
, and
Khonsari
,
M.
,
2006
, “
A Thermohydrodynamic Analysis of Foil Journal Bearings
,”
ASME J. Tribol.
,
128
(
3
), pp.
534
541
.
19.
San Andrés
,
L.
, and
Kim
,
T. H.
,
2010
, “
Thermohydrodynamic Analysis of Bump Type Gas Foil Bearings: A Model Anchored to Test Data
,”
ASME J. Eng. Gas Turbines Power
,
132
(
4
), p.
042504
.
20.
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
.
21.
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
.
22.
Radil
,
K.
,
DellaCorte
,
C.
, and
Zeszotek
,
M.
,
2007
, “
Thermal Management Techniques for Oil-Free Turbomachinery Systems
,”
STLE Tribol. Trans.
,
50
(
3
), pp.
319
327
.
23.
Feng
,
K.
, and
Kaneko
,
S.
,
2009
, “
Thermohydrodynamic Study of Multiwound Foil Bearing Using Lobatto Point Quadrature
,”
ASME J. Tribol.
,
131
(
2
), p.
021702
.
24.
Feng
,
K.
, and
Kaneko
,
S.
,
2013
, “
A Thermohydrodynamic Sparse Mesh Model of Bump Type Foil Bearings
,”
ASME J. Eng. Gas Turbines Power
,
135
(
2
), p.
022501
.
25.
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
.
26.
Kim
,
D.
,
Ki
,
J.
,
Kim
,
Y.
, and
Ahn
,
K.
,
2012
, “
Extended Three-Dimensional Thermo-Hydrodynamic Model of Radial Foil Bearing: Case Studies on Thermal Behaviors and Dynamic Characteristics in Gas Turbine Simulator
,”
ASME J. Eng. Gas Turbines Power
,
134
(
5
), p.
052501
.
27.
San Andrés
,
L.
,
Ryu
,
K.
, and
Kim
,
T.
,
2011
, “
Thermal Management and Rotordynamic Performance of a Hot Rotor-Gas Foil Bearings System—Part I: Measurements
,”
ASME J. Eng. Gas Turbines Power
,
133
(
6
), p.
062501
.
28.
San Andrés
,
L.
,
Ryu
,
K.
, and
Kim
,
T.
,
2011
, “
Thermal Management and Rotordynamic Performance of a Hot Rotor-Gas Foil Bearings System—Part II: Predictions Versus Test Data
,”
ASME J. Eng. Gas Turbines Power
,
133
(
6
), p.
062502
.
29.
Ryu
,
K.
, and
San Andrés
,
L.
,
2012
, “
Effect of Cooling Flow on the Operation of a Hot Rotor-Gas Foil Bearing System
,”
ASME J. Eng. Gas Turbines Power
,
134
(
10
), p.
102511
.
30.
Ryu
,
K.
, and
San Andrés
,
L.
,
2013
, “
On the Failure of a Gas Foil Bearing: High Temperature Operation Without Cooling Flow
,”
ASME J. Eng. Gas Turbines Power
,
135
(
11
), p.
112506
.
31.
Capstone Turbine Corporation
,
2008
, “
Final Technical Report: Advanced Micro Turbine System (AMTS)
,” DOE Project ID No. DE-FC26-00CH11058.
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