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Tribology Transactions Volume 62, 2019 - Issue 6
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Original Articles

Porosity Effect of Sintered Steel on the Frictional Performance of Conformal and Nonconformal Lubricated Contacts

G. BoidiEscola Politécnica, University of São Paulo, São Paulo, BrazilCorrespondence[email protected]
ORCID Iconhttp://orcid.org/0000-0003-0108-3242View further author information
ORCID Icon,
I. S. TertulianoEscola Politécnica, University of São Paulo, São Paulo, BrazilORCID Iconhttp://orcid.org/0000-0001-6753-7927View further author information
ORCID Icon,
L. G. B. S. LimaEscola Politécnica, University of São Paulo, São Paulo, BrazilORCID Iconhttp://orcid.org/0000-0002-4706-7427View further author information
ORCID Icon,
F. J. ProfitoEscola Politécnica, University of São Paulo, São Paulo, BrazilORCID Iconhttp://orcid.org/0000-0003-1531-5040View further author information
ORCID Icon &
I. F. MachadoEscola Politécnica, University of São Paulo, São Paulo, BrazilORCID Iconhttp://orcid.org/0000-0002-1079-0777View further author information
ORCID Icon
Pages 1029-1040 | Received 09 Mar 2019, Accepted 03 Jul 2019, Published online: 08 Aug 2019

References

  • Holmberg, K., Andersson, P., and Erdemir, A. (2012), “Global Energy Consumption Due to Friction in Passenger Cars,” Tribology International, 47, pp 221–234.
  • Hamilton, D. B., Walowit, J. A., and Allen, C. M. (1966), “A Theory of Lubrication by Micro-Irregularities,” Journal of Basic Engineering, 88(1), pp 177–185.
  • Boidi, G., Tertuliano, I. S., Profito, F. J., de Rossi, W., and Machado, I. F. (2019), “Effect of Laser Surface Texturing on Friction Behaviour in Elastohydrodynamically Lubricated Point Contacts under Different Sliding–Rolling Conditions,” Tribology International. Available at: https://doi.org/10.1016/j.triboint.2019.02.021
  • Gachot, C., Rosenkranz, A., Hsu, S. M., and Costa, H. L. (2017), “A Critical Assessment of Surface Texturing for Friction and Wear Improvement,” Wear, 372–373, pp 21–41.
  • Etsion, I., Halperin, G., Brizmer, V., and Kligerman, Y. (2004), “Experimental Investigation of Laser Surface Textured Parallel Thrust Bearings,” Tribology Letters, 17(2), pp 295–300.
  • Etsion, I., Kligerman, Y., and Halperin, G. (1999), “Analytical and Experimental Investigation of Laser-Textured Mechanical Seal Faces,” Tribology Transactions, 42(3), pp 511–516.
  • Etsion, I. (2005), “State of the Art in Laser Surface Texturing,” Journal of Tribology, 127(1), pp 248–253.
  • Brizmer, V., Kligerman, Y., and Etsion, I. (2003), “A Laser Surface Textured Parallel Thrust Bearing,” Tribology Transactions, 46(3), pp 397–403.
  • Hamrock, B. J. and Schmid, S. R. (2004), Fundamental of Fluid Film Lubrication, 2nd ed. Marcel Dekker, Inc.: New York, Basel.
  • Etsion, I. and Halperin, G. (2002), “A Laser Surface Textured Hydrostatic Mechanical Seal,” Tribology Transactions, 45(3), pp 430–434.
  • Dumitru, G., Romano, V., Weber, H. P., Haefke, H., Gerbig, Y., and Pflüger, E. (2007), “Rapid Communication Laser Microstructuring of Steel Surfaces for Tribological Applications,” Applied Physics A, Materials Science & Processing, 487, pp 485–487.
  • Andersson, P., Koskinen, J., Varjus, S., Gerbig, Y., Haefke, H., Georgiou, S., Zhmudd, B., and Buss, W. (2007), “Microlubrication Effect by Laser-Textured Steel Surfaces,” Wear, 262, pp 369–379.
  • Rosenkranz, A., Heib, T., Gachot, C., and Mücklich, F. (2015), “Oil Film Lifetime and Wear Particle Analysis of Laser-Patterned Stainless Steel Surfaces,” Wear, 334–335, pp 1–12.
  • Duarte, B. M., Lasagni, A., Giovanelli, R., Narciso, J., Louis, E., and Mücklich, F. (2008), “Increasing Lubricant Film Lifetime by Grooving Periodical Patterns Using Laser Interference Metallurgy,” Advanced Engineering Materials, 10(6), pp 554–558.
  • Li, X., Sosa, M., and Olofsson, U. (2014), “A Pin-on-Disc Study of the Tribology Characteristics of Sintered versus Standard Steel Gear Materials,” Wear, 340–341, pp 31–40.
  • Fukumasu, N. K., Boidi, G., Seriacopi, V., Machado, G. A. A., Souza, R. M., and Machado, I. F. (2017), “Numerical Analyses of Stress Induced Damage during a Reciprocating Lubricated Test of FeCMo SPS Sintered Alloy,” Tribology International, 113, pp 443–447.
  • Martin, F., García, C., and Blanco, Y. (2015), “Influence of Residual Porosity on the Dry and Lubricated Sliding Wear of a Powder Metallurgy Austenitic Stainless Steel,” Wear, 328–329, pp 1–7.
  • Li, X., Olofsson, U., and Bergseth, E. (2017), “Pin-on-Disc Study of Tribological Performance of Standard and Sintered Gear Materials Treated with Triboconditioning Process: Pretreatment by Pressure-Induced Tribofilm Formation,” Tribology Transactions, 60(1), pp 47–57.
  • Chawla, N. and Deng, X. (2005), “Microstructure and Mechanical Behavior of Porous Sintered Steels,” Materials Science and Engineering A, 390(1–2), pp 98–112.
  • Koval’chenko, M. S. (1991), “Mechanical Properties of Sintered Materials,” Soviet Powder Metallurgy and Metal Ceramics, 30(3), pp 257–261.
  • Straffelini, G., Molinari, A., and Danninger, H. (1999), “Impact Notch Toughness of High-Strength Porous Steels,” Materials Science and Engineering A, 272(2), pp 300–309.
  • Manoylov, A. V., Borodich, F. M., and Evans, H. P. (2013), “Modelling of Elastic Properties of Sintered Porous Materials,” Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences, 469(2154), pp 1–19.
  • Kurgan, N. (2014), “Effect of Porosity and Density on the Mechanical and Microstructural Properties of Sintered 316L Stainless Steel Implant Materials,” Materials & Design, 55, pp 235–241.
  • Li, X. and Olofsson, U. (2017), “A Study on Friction and Wear Reduction Due to Porosity in Powder Metallurgic Gear Materials,” Tribology International, 110, pp 86–95.
  • Li, X., Sosa, M., Andersson, M., and Olofsson, U. (2016), “A Study of the Efficiency of Spur Gears Made of Powder Metallurgy Materials—Ground versus Super-Finished Surfaces,” Tribology International, 95, pp 211–220.
  • Boidi, G., Fukumasu, N. K., and Machado, I. F. (2018), “Wear and Friction Performance under Lubricated Reciprocating Tests of Steel Powder Mixtures Sintered by Spark Plasma Sintering,” Tribology International, 121, pp 139–147.
  • Vlădescu, S. C., Olver, A. V., Pegg, I. G., and Reddyhoff, T. (2015), “The Effects of Surface Texture in Reciprocating Contacts—An Experimental Study,” Tribology International, 82, pp 28–42.
  • Boidi, G., Tertuliano, I. S., Cano, M. F., Machado, G. A. A., Souza, R. M., and Machado, I. F. (2017), Tribological Evaluation of Sintered and Conventional Gear Materials, SAE International. DOI:10.4271/2017-36-0153
  • Zarebski, K. and Putyra, P. (2015), “Iron Powder-Based Graded Products Sintered by Conventional Method and by SPS,” Advanced Powder Technology, 26(2), pp 401–408.
  • Anselmi-Tamburini, U., Garay, J. E., and Munir, Z. A. (2005), “Fundamental Investigations on the Spark Plasma Sintering/Synthesis Process,” Materials Science and Engineering A, 407(1–2), pp 24–30.
  • Orrù, R., Licheri, R., Locci, A. M., Cincotti, A., and Cao, G. (2009), “Consolidation/Synthesis of Materials by Electric Current Activated/Assisted Sintering,” Materials Science and Engineering: R: Reports, 63(4–6), pp 127–287.
  • Seville, J. P. K. and Wu, C.-Y. (2016), Particle Technology and Engineering: An Engineer’s Guide to Particles and Powders: Fundamentals and Computational Approaches. Elsevier/Butterworth-Heinemann: Amsterdam.
  • Panakkal, J. P., Willems, H., and Arnold, W. (1990), “Nondestructive Evaluation of Elastic Parameters of Sintered Iron Powder Compacts,” Journal of Materials Science, 25(2), pp 1397–1402.
  • Greenwood, J. A. and Williamson, J. B. P. (1966), “Contact of Nominally Flat Surfaces,” Proceedings of the Royal Society of London, 295(1442), pp 300–319.
  • Grabon, W., Pawlus, P., Wos, S., Koszela, W., and Wieczorowski, M. (2017), “Effects of Honed Cylinder Liner Surface Texture on Tribological Properties of Piston Ring–Liner Assembly in Short Time Tests,” Tribology International, 113, pp 137–148.
  • Grabon, W., Pawlus, P., Wos, S., Koszela, W., and Wieczorowski, M. (2018), “Effects of Cylinder Liner Surface Topography on Friction and Wear of Liner–Ring System at Low Temperature,” Tribology International, 121, pp 148–160.
  • Reizer, R. and Pawlus, P. (2011), “3D Surface Topography of Cylinder Liner Forecasting during Plateau Honing Process,” Journal of Physics: Conference Series, 311(1), pp 1–6.
  • Gama, A., Cousseau, T., Graça, B., Castro, J., and Seabra, J. (2016), “Experimental Measuring Set-Up and Procedure for Traction Coefficient on Roller-on-Disc Contact,” Lubrication Science, 28, pp 349–362.
  • Ebner, M., Omasta, M., Lohner, T., Šperka, P., Krupka, I., Hartl, M., Michaelis, K., Höhn, B.-R., and Stahl, K. (2018), “Local Effects in EHL Contacts with Oil-Impregnated Sintered Materials,” Lubricants, 7(1), pp 1–21.
  • Wang, X., Zhang, H., and Hsu, S. M. (2007), “The Effects of Dimple Size and Depth on Friction Reduction under Boundary Lubrication Pressure,” Proceedings of the ASME/STLE International Joint Tribology Conference, Parts A and B, San Diego, California, pp 24–26.
  • Mourier, L., Mazuyer, D., Lubrecht, A. A., and Donnet, C. (2006), “Transient Increase of Film Thickness in Micro-Textured EHL Contacts,” Tribology International, 39(12), pp 1745–1756.
  • Pintaude, G. (2013), “Introduction of the Ratio of the Hardness to the Reduced Elastic Modulus for Abrasion,” in Gegner, J. (ed.), Tribology—Fundamentals and Advancements, pp 217–230. Intechopen: Croatia.
  • Masjedi, M. and Khonsari, M. M. (2015), “Tribology International on the Effect of Surface Roughness in Point-Contact EHL: Formulas for Film Thickness and Asperity Load,” Tribiology International, 82, pp 228–244.
  • Mourier, L., Mazuyer, D., Ninove, F. P., and Lubrecht, A. A. (2010), “Lubrication Mechanisms with Laser-Surface-Textured Surfaces in Elastohydrodynamic Regime,” Proceedings of the Institution of Mechanical Engineers - Part J: Journal of Engineering Tribology, 224(8), pp 697–711.
  • Otero, J. E., Lafont Morgado, P., Chacón Tanarro, E., de la Guerra Ochoa, E., Díaz Lantada, A., Munoz-Guijosa, J. M., and Muñoz Sanz, J. L. (2011), “Analytical Model for Predicting the Friction Coefficient in Point Contacts with Thermal Elastohydrodynamic Lubrication,” Proceedings of the Institution of Mechanical Engineers - Part J: Journal of Engineering Tribology, 225(4), pp 181–191.
  • Otero, J. E., de la Guerra Ochoa, E., Tanarro, E. C., Lantada, A. D., and Munoz-Guijosa, J. M. (2016), “Analytical Model for Predicting Friction in Line Contacts,” Lubrication Science, 28, pp 189–205.

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