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General Information

  • ISSN: 2278-0149 (Online)
  • Abbreviated Title:  Int. J. Mech. Eng. Robot. Res.  
  • Editor-in-Chief: ​Prof Richard (Chunhui) Yang, Western Sydney University, Australia
  • Associate Editor: Prof. B.V. Appa Rao, Andhra University; Prof. Ian R. McAndrew, Capitol Technology University, USA
  • Managing Editor: Murali Krishna. B
  • DOI: 10.18178/ijmerr
  • Abstracting/Indexing: Scopus (since 2016), CNKI, Google Scholar, Crossref, etc.
  • E-mail questions to IJMERR Editorial Office.


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International Journal of Mechanical Engineering and Robotics Research

Combined Effects of Rarefaction and Fractal Roughness on the Performance of Ultra-Thin Gas Film Journal Bearings

Abstract—For the aerodynamic microbearings in micro-electro-mechanical systems, the gas film thickness is close to or less than the molecular mean free path. The combined effects of gaseous rarefaction and surface roughness on the performance characteristics of gas journal microbearing must be taken into account during the bearing design. The fractal geometry theory is used to characterize the homogeneous surface roughness on bearing surface, and the generalized modified Reynolds equation with different Poiseuille flow rates are derived and solved by using the partial derivative method and relaxation algorithm. The influences of Knudsen number, fractal dimension and bearing parameters on the load-carrying capacity, friction coefficient and attitude angle are investigated in detail. The results show that the Knudsen number has significant impact on the load-carrying capacity and friction coefficient of slip correction models. The roughness effect increases the load carrying capacity and friction coefficient while the corresponding attitude angles are decreased obviously. 

Index Terms—gaseous rarefaction effects, Poiseuille flow rate, fractal surface roughness, partial derivative method, bearing performance