• citations in SCIndeks: [1]
  • citations in CrossRef:[1]
  • citations in Google Scholar:[]
  • visits in previous 30 days:5
  • full-text downloads in 30 days:4


article: 1 from 2  
Back back to result list
2015, vol. 43, iss. 2, pp. 144-153
Jenkins model based magnetic squeeze film in curved rough circular plates considering slip velocity: A comparison of shapes
Department of Mathematics, Sardar Patel University, Vallabh Vidyanagar, Gujarat, India
An endeavour has been made to compare the performance of a Jenkins model based magnetic squeeze film in curved rough circular plates considering slip velocity for different shapes of the surfaces. Three different shapes (exponential, hyperbolic, secant) have been taken for comparison. Beavers and Joseph's slip model has been considered to analyze the effect of slip. The statistical averaging model of Christensen and Tonder has been adopted to study the effect of surface roughness. The concerned generalized Reynolds type equation is solved to obtain pressure distribution leading to the calculation of load carrying capacity. The results presented in graphical forms establish that Jenkins model modifies the performance in the case of Neuringer-Rosensweig model. The Jenkins model based ferrofluid lubrication moves to a certain extent in reducing the adverse effect of roughness and slip velocity. The extent is more in the case of exponential shape. It is interesting to note that for the exponential shape the combined effect of magnetism and negatively skewed roughness is relatively more, even for higher values of slip parameter.
Abhangi, N.D., Deheri, G.M. (2012) Numerical Modelling of Squeeze Film Performance between Rotating Transversely Rough Curved Circular Plates under the Presence of a Magnetic Fluid Lubricant. ISRN Mechanical Engineering, 2012: 1-9
Agrawal, V.K. (1991) Magnetic-fluid-based porous inclined slider bearing. Wear, Vol. 151, pp. 123-128
Ahmad, N., Singh, J.P. (2007) Magnetic fluid lubrication of porous-pivoted slider bearings with slip velocity. Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology, 221(5): 609-613
Ajwaliya, M.B. (1984) On Certain Theoretical Aspects of Lubrication. India: Sardar Patel University Vallabh Vidyanagar, dissertation
Archibald, F.R. (1956) Load capacity and time relations for squeeze films. Trans. ASME, vol. 78, str. A 231-245
Beavers, G.S., Joseph, D.D. (1967) Boundary conditions at a naturally permeable wall. Journal Fluid Mechanics, vol. 30, part 1, str. 197-207
Bhat, M.V. (2003) Lubrication with a magnetic fluid. India: Team Spirit
Bujurke, N.M., Basti, D.P., Kudenatti, R.B. (2007) Surface roughness effects on squeeze film behavior in porous circular disks with couple stress fluid. Transport in Porous Media, 71(2): 185-197
Cameron, A. (1966) Lectures on the principles of political obligation. London: Longmans
Chiang, H., Hsu, C., Lin, J. (2004) Lubrication performance of finite journal bearings considering effects of couple stresses and surface roughness. Tribology International, 37(4): 297-307
Christensen, H., Tonder, K.C. (1970) The hydrodynamic lubrication of rough bearing surfaces of finite width. in: ASME-ASLE lubrication conference, Paper br. 70-lub-7
Christensen, H., Tonder, K.C. (1969) Tribology of rough surfaces: Stochastic models of hydrodynamic lubrication. SINTEF, Report br. 10/69-18, a
Deheri, G.M., Andharia, P.I., Patel, R.M. (2005) Transversely Rough Slider Bearings with Squeeze Film formed by a Magnetic Fluid. Int. Journal of Applied Mechanics and Engineering, (10): 53-76
Deheri, G.M., Patel, J.R. (2011) Magnetic fluid based squeeze film in a rough Porous parallel plate slider bearing. Annals of Faculty Engg. Hunedoara-Int. Jour. of Engg, Vol. 9, No. 3, pp. 443-448
Deheri, G.M., Patel, H.C., Patel, R.M. (2007) Behavior of Magnetic Fluid based Squeeze Film between Porous Circular Plates with Porous Matrix of Variable Thickness. International Journal of Fluid Mechanics, 34 (6): 506-514
Deheri, G.M., Andharia, P.I., Patel, R.M. (2004) Longitudinally rough slider bearings with squeeze film formed by a magnetic fluid. Industrial Lubrication and Tribology, 56(3): 177-187
Deheri, G.M., Abhangi, N.D. (2008) Squeeze film based on magnetic fluid in curved rough circular plates. Journal of Engineering annals of Faculty of engineering Hunedoara, Vol. 6, No. 2, pp. 95-106
Goldowsky, M. (1980) New methods for sealing, filtering and lubricating with magnetic fluids. IEEE Transactions on Magnetics, 16(2): 382-386
Guha, S.K. (1993) Analysis of dynamic characteristics of hydrodynamic journal bearings with isotropic roughness effects. Wear, Vol. 167, pp.173-179
Gupta, J.L., Deheri, G.M. (1996) Effect of roughness on the behavior of squeeze film in a spherical bearing. Tribology Transactions, 39(1): 99
Gupta, J.L., Vora, K.H. (1980) Analysis of Squeeze Films Between Curved Annular Plates. Journal of Lubrication Technology, 102(1): 48
Hamrock, B.J. (1994) Fundamentals of fluid film lubrication. New York: McGraw-Hill, Inc
Jenkins, J. (1972) A magnetic fluid. Arch. Ration., Mech. Anal, 46(1) 42
Murti, P.R.K. (1975) Squeeze Films in Curved Circular Plates. Journal of Lubrication Technology, 97(4): 650
Naduvinamani, N.B., Fathima, S.T., Hiremath, P.S. (2003) Hydrodynamic lubrication of rough slider bearings with couple stress fluids. Tribology International, 36(12): 949-959
Odenbach, S. (2009) Colloidal Magnetic Fluids: Basics, Development and Application of Ferrofluids. Berlin: Springer
Odenbach, S. (2003) Ferrofluids: magnetically controlled suspensions. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 217(1-3): 171-178
Patel, H., Deheri, G.M., Patel, R.M. (2009) Magnetic fluid‐based squeeze film between porous rotating rough circular plates. Industrial Lubrication and Tribology, 61(3): 140-145
Patel, J.R., Deheri, G.M. (2013) Shliomis Model Based Ferrofluid Lubrication of Squeeze Film in Rotating Rough Curved Circular Disks with Assorted Porous Structures. American Journal of Industrial Engineering, Vol. 1, No. 3, pp. 51-61
Patel, J.R., Deheri, G.M. (2013) Shliomis model based magnetic fluid lubrication of a squeeze film in rotating rough curved circular plates. Caribbean Journal of Science and Technology, Vol. 1, pp. 138-150
Patel, J.R., Deheri, G. (2014) Shliomis model-based magnetic squeeze film in rotating rough curved circular plates: a comparison of two different porous structures. International Journal of Computational Materials Science and Surface Engineering, 6(1): 29
Patel, J.R., Deheri, G. (2014) Theoretical study of Shliomis model based magnetic squeeze film in rough curved annular plates with assorted porous structures. FME Transactions, vol. 42, br. 1, str. 56-66
Patel, J.R., Deheri, G. (2013) Slip Velocity and Roughness Effect on Magnetic Fluid Based Infinitely Long Bearings. Lecture Notes in Mechanical Engineering, : 97-109
Patel, K.C. (1980) The hydromagnetic squeeze film between porous circular disks with velocity slip. Wear, 58(2): 275-281
Patel, N.D., Deheri, G. (2011) Effect of surface roughness on the performance of a magnetic fluid based parallel plate porous slider bearing with slip velocity. Journal of Serbian Society for Computational Mechanics, vol. 5, br. 1, str. 104-118
Patel, R.M., Deheri, G.M., Patel, H.C. (2011) Effect of surface roughness on the behavior of a magnetic fluid based squeeze film between circular plates with porous matrix of variable thickness. Acta Polytechnica Hungarica, Vol. 8, No. 5, pp. 171-190
Prajapati, B.L. (1995) On certain theoretical studies in hydrodynamics and electro magnetohydrodynamic lubrication. Vallabh Vidhyanagar: S.P. University, Dissertation
Prakash, J., Tiwari, K. (1982) Lubrication of a Porous Bearing With Surface Corrugations. Journal of Lubrication Technology, 104(1): 127
Prakash, J., Vij, S.K. (1973) Load Capacity and Time Height Relation between Porous Plates. Wear, 24(3): 309
Raj, K., Moskowitz, B., Casciari, R. (1995) Advances in ferrofluid technology. Journal of Magnetism and Magnetic Materials, 149(1-2): 174-180
Ram, P., Verma, P.D.S. (1999) Ferrofliuid lubrication in porous inclined slider bearing. Indian Journal of Pure and Applied Mathematics, Vol. 30, No. 12, pp. 1273-1281
Rao, R.R., Gouthami, K., Kumar, J.V. (2013) Effects of velocity-slip and viscosity variation in squeeze film lubrication of two circular plates. Tribology in Industry, vol. 35, br. 1, str. 51-60
Rosensweig, R.E. (1985) Ferrohidrodynamics. Cambridge: Cambridge University Press
Salant, R.F., Fortier, A.E. (2004) Numerical Analysis of a Slider Bearing with a Heterogeneous Slip/No-Slip Surface. Tribology Transactions, 47(3): 328-334
Scherer, C., Neto, F.A.M. (2005) Ferrofluids: properties and applications. Brazilian Journal of Physics, 35(3a): 718-727
Shah, R.C., Bhat, M.V. (2002) Ferrofluid lubrication in porous inclined slider bearing with velocity slip. International Journal of Mechanical Sciences, 44(12): 2495-2502
Shimpi, M.E., Deheri, G.M. (2012) Ferrofluid Lubrication of Rotating Curved Rough Porous Circular Plates and Effect of Bearing’s Deformation. Arabian Journal for Science and Engineering, 38(10): 2865-2874
Shimpi, M.E., Deheri, G.M. (2010) Surface roughness and elastic deformation effects on the behaviour of the magnetic fluid based squeeze film between rotating porous circular plates with concentric circular pockets. Tribology in Industry, vol. 32, br. 2, str. 21-30
Shukla, J.B., Kumar, D. (1987) A theory for ferromagnetic lubrication. Journal of Magnetism and Magnetic Materials, 65(2-3): 375-378
Spikes, H., Granick, S. (2003) Equation for Slip of Simple Liquids at Smooth Solid Surfaces. Langmuir, 19(12): 5065-5071
Ting, L.L. (1975) Engagement behaviour of lubricated porous annular disks. Wear, vol. 34, str.p. 159-182, Part I: Squeeze film phase, surface roughness and elastic deformation effects
Troian, S.M., Thompson, P.A. (1997) A general boundary condition for liquid flow at solid surfaces. Nature, 389(6649): 360-362
Tzeng, S.T., Saibel, E. (1967) Surface roughness effect on slider bearing lubrication. Trans. ASME, J. Lub. Tech, vol. 10, str.p. 334-338
Wang, L., Lu, C., Wang, M., Fu, W. (2012) The numerical analysis of the radial sleeve bearing with combined surface slip. Tribology International, 47: 100-104
Wu, C.W., Ma, G.J., Zhou, P., Wu, C.D. (2006) Low Friction and High Load Support Capacity of Slider Bearing With a Mixed Slip Surface. Journal of Tribology, 128(4): 904
Zhu, Y., Granick, S. (2001) Rate-dependent slip of Newtonian liquid at smooth surfaces. Physical review letters, 87(9): 096105