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Improved performance of hydrodynamic bearings by proactiveadjustment

Published online by Cambridge University Press:  14 March 2011

James Keith Martin*
Affiliation:
Department of Design, Development, Environment and Materials, Faculty of Mathematics, Computing and Technology, The Open University, Milton Keynes, MK7 6AA, UK
*
a Corresponding author: [email protected]
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Abstract

There has been a number of initiatives launched in the field of lubrication as potentialsources of improvements in energy efficiency in a wide range of engineering products,plant and processes. Attention is being focussed on bearings to improve both performanceand efficiency in fields such as automotive, machine tools, industrial and powergeneration plant. This paper reviews some of the background to these drives andillustrates how a novel design of adjustable fluid film hydrodynamic journal type bearingshows promise to both improve performance and save energy. Theoretical modelling andpractical tests have demonstrated clear improvements over conventional fluid filmbearings, along with a number of other characteristics offering benefits that may be ofinterest to designers and users of such bearings.

Type
Research Article
Copyright
© AFM, EDP Sciences 2011

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References

H.P. Jost et al., Lubrication (Tribology) Education and research, Report, UK Department of Education and Science, HMSO, London, 1966
Jost, H.P., Schofield, J., Energy saving through tribology: a techno-economic study, Proc. Inst. Mech. Eng., IMechE, London 195 (1981) 151173 CrossRefGoogle Scholar
B. Halligan et al., Tribology action campaign source book, ISBN 0 85298 832 X, IMechE, London, 1992
Martin, J.K., Innovative bearings to improve performance and efficiency in industry, Int. J. Performability Eng. 4 (2008) 34556 Google Scholar
J.K. Martin, Energy savings and improved precision with adjustable hydrodynamic bearings, Proc. STLE 65th Annual Meeting, Las Vegas, 2010
I.F. Santos, E. Estupinan, Three types of active lubrication systems for main bearings of reciprocating engines, Proc. STLE 65th Annual Meeting, Las Vegas, 2010
Martin, J.K., Parkins, D.W., Testing of a large adjustable hydrodynamic journal bearing, Trib. Trans. STLE 44 (2001) 559566 CrossRefGoogle Scholar
J.K. Martin, The potential use of new forms of adjustable hydrodynamic bearings in the intelligent monitoring and maintenance of machine accuracies, Proc. International Conference on Intelligent Maintenance Systems, Xi’an, China, ISBN 7 81099 0144, 2003, pp. 943–950
Santos, I.F., On the adjusting of the dynamic coefficients of tilting – pad journal bearings, Trib. Trans. STLE 38 (1994) 700706 CrossRefGoogle Scholar
Santos, I.F., Russo, F.H., Tilting-pad journal bearings with electronic radial oil injection, J. Trib. Trans. ASME 120 (1998) 583594 CrossRefGoogle Scholar
Santos, I.F., Nicoletti, R., Scalabrin, A., Feasibility of applying active lubrication to reduce vibration in industrial compressors, J. Eng. Gas Turbines Power Trans. ASME 126 (2004) 848854 CrossRefGoogle Scholar
Martin, J.K., Measuring performance of a novel fluid film bearing supporting a rotor on a stationary shaft, by non-contacting means, J. Multi-body Dynamics, Proc. Inst. Mech Eng. Part K 218 (2004) 143151 Google Scholar
Martin, J.K., Parkins, D.W., Some properties of a continuously adjustable hydrodynamic fluid film bearing, Proc. World Tribology Congress, Mech. Eng. Pub., I. MechE. (1997) 184 Google Scholar
Martin, J.K., A Mathematical model and numerical solution technique for a novel adjustable hydrodynamic bearing, Int. J. Numer. Methods Fluids 28 (1999) 845864 3.0.CO;2-O>CrossRefGoogle Scholar
Martin, J.K., Parkins, D.W., Theoretical studies of a continuously adjustable hydrodynamic fluid film bearing, J. Trib. ASME 124 (2002) 203211 CrossRefGoogle Scholar
Martin, J.K., Extended expansion of the Reynolds equation, J. Eng. Trib., Proc. Inst. Mech Eng. Part J 216 (2002) 4951 CrossRefGoogle Scholar
Shenoy, S.B., Pai, R., Steady state performance characteristics of a single pad externally adjustable fluid film bearing, J. Adv. Mech. Design, Systems, and Manufacturing 2 (2008) 937948 CrossRefGoogle Scholar
I.A. Muhsin, Design and evaluation of a novel fluid film journal bearing, Ph.D. Thesis, Cranfield University, UK, 1991