Tribological investigations on MoS2-based nanolubricant for machine tool slideways

Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology

Volumn 229, Issue 5, 2015, Pages 559-567

  Nallasamy, P ^a   Saravanakumar, N ^a   Nagendran, Sumannth ^a   Suriya, E M ^a   Yashwant, D ^a  

^a PSG COLLEGE OF TECHNOLOGY   (India)

Author keywords

anti friction; extreme pressure properties; machine tool slideways; MoS2 nanoparticle; Nanolubricant

Indexed keywords

ENERGY DISPERSIVE SPECTROSCOPY; LAYERED SEMICONDUCTORS; LUBRICANTS; NANOPARTICLES; SCANNING ELECTRON MICROSCOPY; SLIDEWAYS; SLIP FORMING; STICK-SLIP; STRESS ANALYSIS; SULFUR COMPOUNDS; SYNTHESIS (CHEMICAL); TRANSMISSION ELECTRON MICROSCOPY; TRIBOLOGY; WEAR OF MATERIALS;

ACTUAL LOADING CONDITIONS; ANTI-FRICTION; COEFFICIENT OF FRICTIONS; EXTREME PRESSURE PROPERTIES; NANOLUBRICANT; PHYSICAL CHARACTERIZATION; TRIBOLOGICAL CHARACTERISTICS; TRIBOLOGICAL INVESTIGATIONS;

MOLYBDENUM COMPOUNDS;

EID: 84930403159     PISSN: 13506501     EISSN: 2041305X     Source Type: Journal    
DOI: 10.1177/1350650114556394     Document Type: Article

References (27)

1. Xue Q, Liu W, Zhang Z. Friction and wear properties of a surface-modified TiO2 nanoparticle as an additive in liquid paraffin. Wear. 1997 ; 213: 29-32
2. Ghaednia H, Jackson RL. The effect of nanoparticles on the real area of contact, friction and wear. J Tribol. 2013 ; 135 (4). 041603-041603
3. Liu G, Li X, Qin B, et al. Investigation of the mending effect and mechanism of copper nano-particles on a tribologically stressed surface. Tribol Lett. 2004 ; 17: 961-966
4. Xu T, Zhao J, Xu K. The ball-bearing effect of diamond nanoparticles as an oil additive. J Phys D: Appl Phys. 1996 ; 29: 2932-2937
5. Qiu S, Dong J, Chen G. Tribological properties of CeF3 nanoparticles as additives in lubrication oils. Wear. 1999 ; 230: 35-38
6. Rapoport L, Leshchinsky V, Lapsker I, et al. Tribological properties of WS2 nanoparticles under mixed lubrication. Wear. 2003 ; 255 (7). 785-793
7. Ghaednia H, Jackson RL and Khodadadi JM. Experimental analysis of stable CuO nanoparticle enhanced lubricants. J Exp Nanosci 2015; 10(1): 1-18.
8. Greenberg R, Halperin G, Etsion I, et al. The effect of WS 2 nanoparticles on friction reduction in various lubrication regimes. Tribol Lett. 2004 ; 17 (2). 179-186
9. Li B, Wang X, Liu W, et al. Tribochemistry and antiwear mechanism of organic-inorganic nanoparticles as lubricant additives. Tribol Lett. 2006 ; 22 (1). 79-84
10. Ghaednia H, Babaei H, Jackson RL, et al. The effect of nanoparticles on thin film elasto-hydrodynamic lubrication. Appl Phys Lett. 2013 ; 103 (26). 263111-263111
11. Chou R, Viesca JL, Hernandez Battez A, et al. Tribological behavior of polyalphaolefin with the addition of nickel nanoparticles. Tribol Int. 2010 ; 43: 2327-2332
12. Qiu SQ, Zhou ZR. Preparation of Ni nanoparticles and evaluation of their tribological performance as potential additives in oils. J Tribol. 2001 ; 123: 441-441
13. Liu G, Li X, Lu N, et al. Enhancing AW/EP property of lubricant oil by adding nano Al/Sn particles. Tribol Lett. 2005 ; 18: 85-90
14. Liu W, Chen S. An investigation of the tribological behaviour of surface-modified ZnS nanoparticles in liquid paraffin. Wear. 2000 ; 238: 120-124
15. Viesca JL, Hernandez Battez A, Gonzalez R, et al. Antiwear properties of carbon-coated copper nanoparticles used as an additive to a polyalphaolefin. Tribol Int. 2011 ; 44: 829-833
16. Suter P Bulletin MRS. Pittsburgh, PA: The Materials Research Society Pittsburgh ; 1991: 24-24.
17. Bai Y, Xing J, Ma S, et al. Effect of MoS2 on the tribological properties of in situ Fe3Al-20 wt% Al2O3-4 wt% Cr composites. Proc IMechE, Part J: J Engineering Tribology 2013. DOI: 10. 1177/1350650113479249.
18. Hampson MR, Roberts EW, Cropper MD, et al. Towards the effective solid lubrication of ball bearings operating at high temperature. Proc IMechE, Part J: J Engineering Tribology. 2008 ; 222 (8). 1041-1049
19. Verma A, Jiang WP, Abu Safe HH, et al. Tribological behavior of deagglomerated active inorganic nanoparticles for advanced lubrication. Tribol Trans. 2008 ; 51: 673-678
20. Shen B, Shih A, Malshe A, et al. Performance of novel MoS2 nanoparticles based grinding fluids in minimum quantity lubrication grinding. Trans NAMRI/SME. 2008 ; 36: 357-364
21. Kalin M, Kogovsek J, Remskar M. Mechanisms and improvements in the friction and wear behavior using MoS2 nanotubes as potential oil additives. Wear. 2012 ; 280 - 281: 36-45
22. Cizaire L, Vacher B, Le-Mogne T, et al. Mechanisms of ultra-low friction by hollow inorganic fullerene-like MoS2 nanoparticles. Surf Coat Tehnol. 2002 ; 160: 282-287
23. Hu KH, Liu M, Wang QJ, et al. Tribological properties of molybdenum disulphide nanosheets by nanolayer restacking process as additive in liquid paraffin. Tribol Int. 2009 ; 42: 33-39
24. Chevron Philips Chemical Company. Safe handling and storage of synfluid, polyalphaolefins (PAO), 2008.
25. Wu YY, Tsui WC, Liu TC. Experimental analysis of tribological properties of lubricating oils with nanoparticle additives. Wear. 2007 ; 262: 819-825
26. Joshi PH. Machine tools handbook - design and operation. New Delhi, India: Tata McGraw Hill Education Private Limited, 2007, pp.459-506.
27. ASTM Standard D2783-03. Standard test method for measurement of extreme-pressure properties of lubricating fluids (four-ball method). West Conshohocken, PA: ASTM International; 2009.