Open Access
Issue
Mécanique & Industries
Volume 12, Number 1, 2011
Page(s) 17 - 24
DOI https://doi.org/10.1051/meca/2011005
Published online 14 March 2011
  1. H.P. Jost et al., Lubrication (Tribology) Education and research, Report, UK Department of Education and Science, HMSO, London, 1966 [Google Scholar]
  2. H.P. Jost, J. Schofield, Energy saving through tribology: a techno-economic study, Proc. Inst. Mech. Eng., IMechE, London 195 (1981) 151–173 [Google Scholar]
  3. B. Halligan et al., Tribology action campaign source book, ISBN 0 85298 832 X, IMechE, London, 1992 [Google Scholar]
  4. J.K. Martin, Innovative bearings to improve performance and efficiency in industry, Int. J. Performability Eng. 4 (2008) 345–56 [Google Scholar]
  5. J.K. Martin, Energy savings and improved precision with adjustable hydrodynamic bearings, Proc. STLE 65th Annual Meeting, Las Vegas, 2010 [Google Scholar]
  6. 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 [Google Scholar]
  7. J.K. Martin, D.W. Parkins, Testing of a large adjustable hydrodynamic journal bearing, Trib. Trans. STLE 44 (2001) 559–566 [CrossRef] [Google Scholar]
  8. 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 [Google Scholar]
  9. I.F. Santos, On the adjusting of the dynamic coefficients of tilting – pad journal bearings, Trib. Trans. STLE 38 (1994) 700–706 [CrossRef] [Google Scholar]
  10. I.F. Santos, F.H. Russo, Tilting-pad journal bearings with electronic radial oil injection, J. Trib. Trans. ASME 120 (1998) 583–594 [CrossRef] [Google Scholar]
  11. I.F. Santos, R. Nicoletti, A. Scalabrin, Feasibility of applying active lubrication to reduce vibration in industrial compressors, J. Eng. Gas Turbines Power Trans. ASME 126 (2004) 848–854 [CrossRef] [Google Scholar]
  12. J.K. Martin, 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) 143–151 [Google Scholar]
  13. J.K. Martin, D.W. Parkins, Some properties of a continuously adjustable hydrodynamic fluid film bearing, Proc. World Tribology Congress, Mech. Eng. Pub., I. MechE. (1997) 184 [Google Scholar]
  14. J.K. Martin, A Mathematical model and numerical solution technique for a novel adjustable hydrodynamic bearing, Int. J. Numer. Methods Fluids 28 (1999) 845–864 [Google Scholar]
  15. J.K. Martin, D.W. Parkins, Theoretical studies of a continuously adjustable hydrodynamic fluid film bearing, J. Trib. ASME 124 (2002) 203–211 [CrossRef] [Google Scholar]
  16. J.K. Martin, Extended expansion of the Reynolds equation, J. Eng. Trib., Proc. Inst. Mech Eng. Part J 216 (2002) 49–51 [CrossRef] [Google Scholar]
  17. S.B. Shenoy, R. Pai, Steady state performance characteristics of a single pad externally adjustable fluid film bearing, J. Adv. Mech. Design, Systems, and Manufacturing 2 (2008) 937–948 [CrossRef] [Google Scholar]
  18. I.A. Muhsin, Design and evaluation of a novel fluid film journal bearing, Ph.D. Thesis, Cranfield University, UK, 1991 [Google Scholar]

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