Friction is usually induced when the contacts are in relative motion, leading to mechanical vibration and consequently heat generation. The reduction of these undesirable parameters is possible by the application of greases, which intends to increase the service life of the bearings. The present work incorporates the frictional and vibration behaviors of concentrated point contact lubricated with bare and nanocomposite greases. The nanocomposite greases were formulated by dispersing different categories of nano-additives like reduced graphene oxide (rGO), calcium carbonate (CaCO3), and alumina (α-Al2O3) in bare grease (BG). The formulated nanocomposite greases are tested for film formation, frictional and vibrational response under a limited supply of greases. The use of transparent glass disk better analyses the profile of film thickness to understand the lubrication mechanism of the point contact. The microstructure of nano-additives and the formulated nanocomposite greases were characterized using high-resolution transmission electron microscopy (HRTEM). The presence of different functional groups in nano-additives and the formulated nanocomposite greases were characterized using Raman spectroscopy. The tribological contact operates under 3% and 30% slide-roll-ratio (SRR) for varying rolling speed (0.001–1 m/s) at a load of 30 N (Hertzian pressure, pH = 0.9 GPa). Film thickness, friction and vibration behavior were recorded to focus the tribo-performance, degree of starvation and dynamics of the tribological contact with slip varying from 3% to 30% SRR. The vibration level was refined to 32% with the addition of rGO nanosheets in BG. The incompatibility of α-Al2O3 with the grease structure results in disruption of tribo-dynamics behavior of the point contact.
Issue Section:
Elastohydrodynamic Lubrication
References
1.
Cousseau
, T.
, Bjorling
, M.
, Graca
, B.
, Campos
, A.
, Seabra
, J.
, and Larsson
, R.
, 2012
, “Film Thickness in a Ball-on-Disc Contact Lubricated With Greases, Bleed Oils and Base Oils
,” Tribol. Int.
, 53
, pp. 53
–60
.2.
Wilson
, A. R.
, 1979
, “The Relative Thickness of Grease and Oil Films in Rolling Bearings
,” Proc. Inst. Mech. Eng.
, 193
(1
), pp. 185
–192
.3.
Johnston
, G. J.
, Wayte
, R.
, and Spikes
, H. A.
, 1991
, “The Measurement and Study of Very Thin Lubricant Films in Concentrated Contacts
,” Tribol. Trans.
, 34
(2
), pp. 187
–194
.4.
Cann
, P. M.
, Spikes
, H. A.
, and Hutchinson
, J.
, 1996
, “The Development of a Spacer Layer Imaging Method (SLIM) for Mapping Elastohydrodynamic Contacts
,” Tribol. Trans.
, 39
(4
), pp. 915
–921
.5.
Spikes
, H. A.
, and Cann
, P. M.
, 2001
, “The Development and Application of the Spacer Layer Imaging Method for Measuring Lubricant Film Thickness
,” Proc. Inst. Mech. Eng., Part J
, 215
(3
), pp. 261
–277
.6.
Smeeth
, M.
, and Spikes
, H. A.
, 1996
, “The Influence of Slide/Roll Ratio on the Film Thickness of an EHD Contact Operating Within the Mixed Lubrication Regime
,” Tribol. Ser.
, 31
, pp. 695
–703
.7.
Huang
, L.
, Guo
, D.
, Wen
, S.
, and Wan
, G. T. Y.
, 2014
, “Effects of Slide/Roll Ratio on the Behaviours of Grease Reservoir and Film Thickness of Point Contact
,” Tribol. Lett.
, 54
(3
), pp. 263
–271
.8.
Gonçalves
, D.
, Graça
, B.
, Campos
, A.
, and Seabra
, J.
, 2016
, “On the Friction Behaviour of Polymer Greases
,” Tribol. Int.
, 93
, pp. 399
–410
.9.
Ranganath Nayak
, P.
, 1972
, “Contact Vibrations
,” J. Sound Vib.
, 22
(3
), pp. 297
–322
.10.
Liu
, T.
, Li
, G.
, Wei
, H.
, and Sun
, D.
, 2016
, “Experimental Observation of Cross Correlation Between Vibration and Normal Friction Vibration in a Running-in Process
,” Tribol. Int.
, 97
, pp. 77
–88
.11.
Sinou
, J.-J.
, Cayer-Barrioz
, J.
, and Berro
, H.
, 2013
, “Friction-Induced Vibration of a Lubricated Mechanical System
,” Tribol. Int.
, 61
, pp. 156
–168
.12.
Soobbarayen
, K.
, Besset
, S.
, and Sinou
, J.-J.
, 2013
, “Noise and Vibration for a Self-Excited Mechanical System With Friction
,” Appl. Acoust.
, 74
(10
), pp. 1191
–1204
.13.
Lundberg
, O. E.
, Finnveden
, S.
, Bjorklund
, S.
, Parssinen
, M.
, and Lopez Arteaga
, I.
, 2015
, “A Nonlinear State-Dependent Model for Vibrations Excited by Roughness in Rolling Contacts
,” J. Sound Vib.
, 345
, pp. 197
–213
.14.
Sayles
, R. S.
, and Poon
, S. Y.
, 1981
, “Surface Topography and Rolling Element Vibration
,” Precis. Eng.
, 3
(3
), pp. 137
–144
.15.
Shi
, X.
, and Polycarpou
, A. A.
, 2005
, “Measurement and Modeling of Normal Contact Stiffness and Contact Damping at the Meso Scale
,” ASME J. Vib. Acoust.
, 127
(1
), pp. 52
–60
.16.
De Laurentis
, N.
, Kadiric
, A.
, Lugt
, P.
, and Cann
, P.
, 2016
, “The Influence of Bearing Grease Composition on Friction in Rolling/Sliding Concentrated Contacts
,” Tribol. Int.
, 94
, pp. 624
–632
.17.
Couronne
, I.
, Vergne
, P.
, Mazuyer
, D.
, Truong-Dinh
, N.
, and Girodin
, D.
, 2003
, “Effects of Grease Composition and Structure on Film Thickness in Rolling Contact
,” Tribol. Trans.
, 46
(1
), pp. 31
–36
.18.
Gentle
, C. R.
, 1983
, “Effect of Proprietary Oil Additives on Elastohydrodynamic Film Thickness
,” Tribol. Int.
, 16
(4
), pp. 193
–197
.19.
Zulkifli
, N. W. M.
, Kalam
, M. A.
, Masjuki
, H. H.
, and Yunus
, R.
, 2013
, “Experimental Analysis of Tribological Properties of Biolubricant With Nanoparticle Additive
,” Procedia Eng.
, 68
, pp. 152
–157
.20.
Hu
, Z. S.
, Lai
, R.
, Lou
, F.
, Wang
, L. G.
, Chen
, Z. L.
, Chen
, G. X.
, and Dong
, J. X.
, 2002
, “Preparation and Tribological Properties of Nanometer Magnesium Borate as Lubricating Oil Additive
,” Wear
, 252
(5–6
), pp. 370
–374
.21.
Wu
, Y. Y.
, Tsui
, W. C.
, and Liu
, T. C.
, 2007
, “Experimental Analysis of Tribological Properties of Lubricating Oils With Nanoparticle Additives
,” Wear
, 262
(7–8
), pp. 819
–825
.22.
Qiu
, S.
, Zhou
, Z.
, Dong
, J.
, and Chen
, G.
, 2001
, “Preparation of Ni Nanoparticles and Evaluation of Their Tribological Performance as Potential Additives in Oils
,” ASME J. Tribol.
, 123
(3
), pp. 441
–443
.23.
Rapoport
, L.
, Leshchinsky
, V.
, Lapsker
, I.
, Volovik
, Y.
, Nepomnyashchy
, O.
, Lvovsky
, M.
, Popovitz-biro
, R.
, Feldman
, Y.
, and Tenne
, R.
, 2003
, “Tribological Properties of WS2 Nanoparticles Under Mixed Lubrication
,” Wear
, 255
(7–12
), pp. 785
–793
.24.
Jiao
, D.
, Zheng
, S.
, Wang
, Y.
, Guan
, R.
, and Cao
, B.
, 2011
, “The Tribology Properties of Alumina/Silica Composite Nanoparticles as Lubricant Additives
,” Appl. Surf. Sci.
, 257
(13
), pp. 5720
–5725
.25.
Wang
, L.
, Wang
, B.
, Wang
, X.
, and Liu
, W.
, 2007
, “Tribological Investigation of CaF2 Nanocrystals as Grease Additives
,” Tribol. Int.
, 40
(7
), pp. 1179
–1185
.26.
Zhao
, G.
, Zhao
, Q.
, Li
, W.
, Wang
, X.
, and Liu
, W.
, 2014
, “Tribological Properties of Nano-Calcium Borate as Lithium Grease Additive
,” Lubr. Sci.
, 26
(1
), pp. 43
–53
.27.
Pena-Paras
, L.
, Taha-Tijerina
, J.
, Garcia
, A.
, Maldonado
, D.
, Najera
, A.
, Cantu
, P.
, and Ortiz
, D.
, 2015
, “Thermal Transport and Tribological Properties of Nanogreases for Metal-Mechanic Applications
,” Wear
, 332
, pp. 1322
–1326
.28.
Chen
, J.
, 2010
, “Tribological Properties of Polytetrafluoroethylene, Nano-Titanium Dioxide, and Nano-Silicon Dioxide as Additives in Mixed Oil-Based Titanium Complex Grease
,” Tribol. Lett.
, 38
(3
), pp. 217
–224
.29.
Chen
, H.
, Wei
, H.
, Chen
, M.
, Meng
, F.
, Li
, H.
, and Li
, Q.
, 2013
, “Enhancing the Effectiveness of Silicone Thermal Grease by the Addition of Functionalized Carbon Nanotubes
,” Appl. Surf. Sci.
, 283
, pp. 525
–531
.30.
Martin
, J. M.
, and Ohmae
, N.
, 2008
, Nanolubricants
, Vol. 13
, Wiley
, Chichester, UK
.31.
Dai
, W.
, Kheireddin
, B.
, Gao
, H.
, and Liang
, H.
, 2016
, “Roles of Nanoparticles in Oil Lubrication
,” Tribol. Int.
, 102
, pp. 88
–98
.32.
Choudhary
, S.
, Mungse
, H. P.
, and Khatri
, O. P.
, 2012
, “Dispersion of Alkylated Graphene in Organic Solvents and Its Potential for Lubrication Applications
,” J. Mater. Chem.
, 22
(39
), pp. 21032
–21039
.33.
Mungse
, H. P.
, and Khatri
, O. P.
, 2014
, “Chemically Functionalized Reduced Graphene Oxide as a Novel Material for Reduction of Friction and Wear
,” J. Phys. Chem. C
, 118
(26
), pp. 14394
–14402
.34.
Lee
, C.
, Li
, Q.
, Kalb
, W.
, Liu
, X.-Z.
, Berger
, H.
, Carpick
, R. W.
, and Hone
, J.
, 2010
, “Frictional Characteristics of Atomically Thin Sheets
,” Science
, 328
(5974
), pp. 76
–80
.35.
Ji
, X.
, Chen
, Y.
, Zhao
, G.
, Wang
, X.
, and Liu
, W.
, 2011
, “Tribological Properties of CaCO3 Nanoparticles as an Additive in Lithium Grease
,” Tribol. Lett.
, 41
(1
), pp. 113
–119
.36.
Jin
, D.
, and Yue
, L.
, 2008
, “Tribological Properties Study of Spherical Calcium Carbonate Composite as Lubricant Additive
,” Mater. Lett.
, 62
(10–11
), pp. 1565
–1568
.37.
Zhang
, M.
, Wang
, X.
, Fu
, X.
, and Xia
, Y.
, 2009
, “Performance and Anti-Wear Mechanism of CaCO3 Nanoparticles as a Green Additive in Poly-Alpha-Olefin
,” Tribol. Int.
, 42
(7
), pp. 1029
–1039
.38.
Radice
, S.
, and Mischler
, S.
, 2006
, “Effect of Electrochemical and Mechanical Parameters on the Lubrication Behaviour of Al2O3 Nanoparticles in Aqueous Suspensions
,” Wear
, 261
(9
), pp. 1032
–1041
.39.
Singh
, J.
, Kumar
, D.
, and Tandon
, N.
, 2017
, “Tribological and Vibration Studies on Newly Developed Nano-Composite Greases Under Boundary Lubrication Regime
,” ASME J. Tribol.
, 140
(3), pp. 32001
–32010
.40.
Singh
, J.
, Anand
, G.
, Kumar
, D.
, and Tandon
, N.
, 2016
, “Graphene Based Composite Grease for Elastohydrodynamic Lubricated Point Contact
,” IOP Conf. Ser.: Mater. Sci. Eng.
, 149
, p. 012195.41.
Singh
, J.
, Kumar
, D.
, and Tandon
, N.
, 2017
, “Development of Nanocomposite Grease: Microstructure, Flow, and Tribological Studies
,” ASME J. Tribol.
, 139
(5), p. 052001.42.
Katagiri
, G.
, Ishida
, H.
, and Ishitani
, A.
, 1988
, “Raman Spectra of Graphite Edge Planes
,” Carbon
, 26
(4
), pp. 565
–571
.43.
Wan
, Q.
, Jin
, Y.
, Sun
, P.
, and Ding
, Y.
, 2014
, “Rheological and Tribological Behaviour of Lubricating Oils Containing Platelet MoS2 Nanoparticles
,” J. Nanopart. Res.
, 16
, p. 2386.44.
Xu
, N.
, Zhang
, M.
, Li
, W.
, Zhao
, G.
, Wang
, X.
, and Liu
, W.
, 2013
, “Study on the Selectivity of Calcium Carbonate Nanoparticles Under the Boundary Lubrication Condition
,” Wear
, 307
(1–2
), pp. 35
–43
.45.
Bouzidi
, M.
, Firdaouss
, M.
, and Lallemand
, P.
, 2001
, “Momentum Transfer of a Boltzmann-Lattice Fluid With Boundaries
,” Phys. Fluids
, 13
(11
), pp. 3452
–3459
.46.
Ochoa-Tapia
, Alberto
, J.
, and Whitaker
, S.
, 1995
, “Momentum Transfer at the Boundary Between a Porous Medium and a Homogeneous fluid—Part I: Theoretical Development
,” Int. J. Heat Mass Transfer
, 38
(14
), pp. 2635
–2646
.47.
Cann
, P. M.
, 1999
, “Starved Grease Lubrication of Rolling Contacts
,” Tribol. Trans.
, 42
(4
), pp. 867
–873
.48.
Dareing
, D. W.
, and Jhonson
, K. L.
, 1975
, “Fluid Film Damping of Rolling Contact Vibrations
,” J. Mech. Eng. Sci.
, 17
(4
), pp. 214
–218
.49.
Johnson
, K. L.
, Greenwood
, J. A.
, and Poon
, S. Y.
, 1972
, “A Simple Theory of Asperity Contact in Elastohydrodynamic Lubrication
,” Wear
, 19
(1
), pp. 91
–108
.50.
Wang
, W.
, Wang
, S.
, Shi
, F.
, Wang
, Y.
, Chen
, H.
, Wang
, H.
, and Hu
, Y.
, 2007
, “Simulations and Measurements of Sliding Friction Between Rough Surfaces in Point Contacts: From EHL to Boundary Lubrication
,” ASME J. Tribol.
, 129
(3
), pp. 495
–501
.51.
Sudeep
, U.
, Pandey
, R. K.
, and Tandon
, N.
, 2013
, “Effects of Surface Texturing on Friction and Vibration Behaviors of Sliding Lubricated Concentrated Point Contacts Under Linear Reciprocating Motion
,” Tribol. Int.
, 62
, pp. 198
–207
.52.
Wijnant
, Y. H.
, Venner
, C. H.
, Larsson
, R.
, and Eriksson
, P.
, 1999
, “Effects of Structural Vibrations on the Film Thickness in an EHL Circular Contact
,” ASME J. Tribol.
, 121
(2
), pp. 259
–264
.53.
Shu
, J.
, Harris
, K.
, Munavirov
, B.
, Westbroek
, R.
, Leckner
, J.
, and Glavatskih
, S.
, 2018
, “Tribology of Polypropylene and Li-Complex Greases With ZDDP and MoDTC Additives
,” Tribol. Int.
, 118
, pp. 189
–195
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