Foil bearings (FB) are one type of hydrodynamic air/gas bearings but with a compliant bearing surface supported by structural material that provides stiffness and damping to the bearing. The hybrid foil bearing (HFB) in this paper is a combination of a traditional hydrodynamic foil bearing with externally pressurized air/gas supply system to enhance load capacity during the start and to improve thermal stability of the bearing. The HFB is more suitable for relatively large and heavy rotors where rotor weight is comparable to the load capacity of the bearing at full speed and extra air/gas supply system is not a major added cost. With 4448–22,240 N thrust class turbine aircraft engines in mind, the test rotor is supported by HFB in one end and duplex rolling element bearings (REB) in the other end. This paper presents experimental work on HFB with diameter of 102 mm performed at the U.S. Air force Research Laboratory (AFRL). Experimental works include: measurement of impulse response of the bearing to the external load corresponding to rotor's lateral acceleration of 5.55 g, forced response to external subsynchronous excitation, and high-speed imbalance response. A nonlinear rotordynamic simulation model was also applied to predict the impulse response and forced subsynchronous response. The simulation results agree well with the experimental results. Based on the experimental results and subsequent simulations, an improved HFB design is also suggested for higher impulse load capability up to 10 g and rotordynamics stability up to 30,000 rpm under subsynchronous excitation.
Issue Section:
Gas Turbines: Structures and Dynamics
References
1.
Capstone Turbine Corporation, 2017, “Description of Capstone Microturbines,” Capstone Turbine Corporation, Chatsworth, CA, accessed Aug. 25, 2017, https://www.capstoneturbine.com
2.
KTURBO, 2017, “
Descriptions of KTURBO, Inc., Product Line of Turbo Blowers, Turbo Compressors, and Generators
,” KTURBO, Inc., Chungbuk, South Korea, accessed Aug. 25, 2017, http://eng.kturbo.com/products/products02.jsp3.
Neuros, 2017, “
Descriptions of Neuros Co. Ltd, Product Line of Turbo Blowers, Turbo Compressors, and Generators
,” Neuros Co., Ltd., Daejeon, South Korea, accessed Aug. 25, 2017, http://www.neuros.com/4.
Bladon Jets, 2017, “
Description of Micro Gensets
,” Bladon Jets, Coventry, UK, accessed Aug. 25, 2017, http://www.bladonjets.com5.
Agrawal
, G. L.
, 1997
, “Foil Air/Gas Bearing Technology—An Overview
,” ASME
Paper No. 97-GT-347.6.
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.
Heshmat
, C. A.
, Xu
, D. S.
, and Heshmat
, H.
, 2000
, “Analysis of Gas Lubricated Foil Thrust Bearings Using Coupled Finite Element and Finite Difference Methods
,” ASME J. Tribol.
, 122
(1
), pp. 199
–204
.8.
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
.9.
Carpino
, M.
, and Talmage
, G.
, 2003
, “A Fully Coupled Finite Element Formulation for Elastically Supported Foil Journal Bearings
,” STLE Tribol. Trans.
, 46
(3
), pp. 560
–565
.10.
Kim
, T. H.
, and San Andrés
, L.
, 2007
, “Analysis of Advanced Gas Foil Bearings With Piecewise Linear Elastic Supports
,” Tribol. Int.
, 40
(8
), pp. 1239
–1245
.11.
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. GT2007-27249.12.
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
.13.
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
.14.
San Andrés
, S. L.
, and Kim
, T. H.
, 2008
, “Forced Nonlinear Response of Gas Foil Bearing Supported Rotors
,” Tribol. Int.
, 41
(8
), pp. 704
–715
.15.
Rudloff
, L.
, Arghir
, M.
, Bonneau
, O.
, and Matta
, P.
, 2011
, “Experimental Analyses of a First Generation Foil Bearing: Startup Torque and Dynamic Coefficients
,” ASME J. Eng. Gas Turbines Power
, 133
(9
), p. 092501
.16.
Balducchi
, F.
, Arghir
, M.
, and Gaudillere
, S.
, 2014
, “Experimental Analysis of the Unbalance Response of Rigid Rotors Supported on Aerodynamic Foil Bearings
,” ASME
Paper No. GT2014-25552.17.
DellaCorte
, C.
, and Valco
, M. J.
, 2000
, “Load Capacity Estimation of Foil Air Journal Bearings for Oil-Free Turbo-Machinery Applications
,” STLE Tribol. Trans.
, 43
(4
), pp. 795
–801
.18.
Bryant
, M. D.
, Khonsari
, M. M.
, and Ling
, F. F.
, 2008
, “On the Thermodynamics of Degradation
,” Proc. R. Soc.
, A464
(2096), pp. 2001
–2014
.19.
Doelling
, K. L.
, Ling
, F. F.
, Bryant
, M. D.
, and Heilman
, B. P.
, 2000
, “An Experimental Study of the Correlation between Wear and Entropy Flow in Machinery Components
,” J. Appl. Phys.
, 88
(5
), pp. 2299
–3003
.http://www.me.utexas.edu/~bryant/research/RecentPublications/DeollingLingBryantJAP.pdf20.
Swanson
, E. E.
, and Heshmat
, H.
, 2002
, “Oil-Free Foil Bearings as a Reliable, High Performance Backup Bearing for Active Magnetic Bearings
,” ASME
Paper No. GT2002-30291.21.
Swanson
, E. E.
, Heshmat
, H.
, and Walton
, J.
, 2002
, “Performance of a Foil-Magnetic Hybrid Bearing
,” ASME J. Eng. Gas Turbines Power
, 124
(2
), pp. 375
–381
.22.
Kim
, D.
, and Park
, S.
, 2009
, “Hydrostatic Air Foil Bearings: Analytical and Experimental Investigations
,” Elsevier Tribol. Int.
, 42
(3
), pp. 413
–425
.23.
Kumar
, M.
, and Kim
, D.
, 2010
, “Static Performance of Hydrostatic Air Bump Foil Bearing
,” Tribol. Int.
, 43
(4
), pp. 752
–758
.24.
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
.25.
Kim
, D.
, and Zimbru
, G.
, 2012
, “Start-Stop Characteristics and Thermal Behavior of a Large Hybrid Airfoil Bearing for Aero-Propulsion Applications
,” ASME J. Eng. Gas Turbines Power
, 134
(3
), p. 032502
.26.
Kim
, D.
, and Varrey
, M.
, 2012
, “Imbalance Response and Stability Characteristics of a Rotor Supported by Hybrid Air Foil Bearings
,” STLE Tribol. Trans.
, 55
(4
), pp. 529
–538
.27.
Wang
, Y.
, and Kim
, D.
, 2013
, “Experimental Identification of Force Coefficients of Large Hybrid Air Foil Bearings
,” ASME J. Eng. Gas Turbines Power
, 136
(3
), p. 032503
.28.
Lund
, J. W.
, 1964
, “The Hydrostatic Gas Journal Bearing With Journal Rotation and Vibration
,” ASME J. Basic Eng.
, 86
(2
), pp. 328
–336
.29.
Lund
, J. W.
, 1967
, “A Theoretical Analysis of Whirl Instability and Pneumatic Hammer for a Rigid Rotor in Pressurized Gas Journal Bearings
,” ASME J. Lubr. Technol.
, 89
(2
), pp. 154
–166
.30.
Mori
, H.
, and Miyamatsu
, Y.
, 1969
, “Theoretical Flow-Models for Externally Pressurized Gas Bearings
,” ASME J. Lubr. Technol.
, 91
(1), pp. 183
–193
.31.
Bassani
, R.
, Ciulli
, E.
, and Forte
, P.
, 1989
, “Pneumatic Stability of the Integral Externally Pressurized Gas Bearing. Comparison With Other Types of Bearing
,” Tribol. Int.
, 22
(6
), pp. 363
–374
.32.
Han
, D. C.
, Park
, S. S.
, and Kim
, W. J.
, 1994
, “A Study on the Characteristics of Externally Pressurized Gas Bearings
,” Precis. Eng.
, 16
(3
), pp. 164
–173
.33.
Brzeski
, L.
, Kazimierski
, Z.
, and Lech
, T.
, 1999
, “Experimental Investigations of Precision Spindles Equipped With High Stiffness Gas Journal Bearings
,” Precis. Eng.
, 23
(3
), pp. 155
–163
.34.
Belforte
, G.
, Raparelli
, T.
, and Viktorov
, V.
, 2006
, “An Experimental Study of High-Speed Rotor Supported by Air Bearings: Test RIG and First Experimental Results
,” Tribol. Int.
, 39
(8
), pp. 839
–845
.35.
Curwen
, P. W.
, Frost
, A.
, and Lund
, J. W.
, 1969
, “High-Performance Turboalternator and Associated Hardware—2: Design of Gas Bearings
,” NASA Lewis Research Center, Cleveland, OH, Technical Report No. NASA-CR-1291
.https://www.google.co.in/url?sa=t&rct=j&q=&esrc=s&source=web&cd=2&ved=0ahUKEwjnj6Tq6fHVAhXl44MKHYieBN4QFggnMAE&url=http%3A%2F%2Fwww.dtic.mil%2Fget-tr-doc%2Fpdf%3FAD%3DADA380027&usg=AFQjCNFLto2a3CGveQlcvJN0Ahz_gzE9dQ36.
San Andrés
, L.
, 2006
, “Hybrid Flexure Pivot-Tilting Pad Gas Bearings: Analysis and Experimental Validation
,” ASME J. Tribol.
, 128
(3
), pp. 551
–558
.37.
Eshel
, A.
, 1979
, “Numerical Solution of the Planar Hydrostatic Foil Bearing
,” ASME J. Lubr. Technol.
, 101
(1
), pp. 86
–91
.38.
Bosley
, R. W.
, and Miller
, R. F.
, 1998
, “Hydrostatic Augmentation of a Compliant Foil Hydrodynamic Fluid Film Thrust Bearing
,” Capstone Turbine Corporation, Vilnius, Lithuania, US Patent No. US5827040 A
.https://www.google.com/patents/US582704039.
Jones
, A. B.
, 1960
, “A General Theory for Elastically Constrained Ball and Radial Roller Bearings Under Arbitrary Load and Speed Conditions
,” J. Basic Eng.
, 82
(2
), pp. 309
–320
.40.
Kim
, D.
, Lee
, A.
, and Choi
, B.
, 2013
, “Evaluation of Foil Bearing Performance and Nonlinear Rotordynamics of 120kW Oil-Free Gas Turbine Generator
,” ASME J. Eng. Gas Turbines Power
, 136
(3
), p. 032504
.41.
Kumar
, M.
, and Kim
, D.
, 2008
, “Parametric Studies on Dynamic Performance of Hybrid Airfoil Bearings
,” ASME J. Eng. Gas Turbines Power
, 130
(6
), p. 062501
.Copyright © 2018 by ASME
You do not currently have access to this content.
