Volume 5, Issue 2, April 2017, Page: 78-86
Temperature Resistance of the Boundary Lubrication Layers Under Rolling with Slippage Condition
Tareq M. A. Al-Quraan, Technical Sciences Department, College of Ma’an, Al-Balqa Applied University, Al-Salt, Jordan
Oksana O. Mikosyanchik, Life Safety Department, National Aviation University, Kiev, Ukraine
Rudolph G. Mnatsakanov, Organization of Aviation Works and Services Department, National Aviation University, Kiev, Ukraine
Received: Feb. 9, 2017;       Accepted: Feb. 21, 2017;       Published: Mar. 7, 2017
DOI: 10.11648/j.ijmea.20170502.12      View  1730      Downloads  103
Abstract
The influence of slip velocity at rolling with slippage on the intensity of heat release in the local contact at different modes of lubricating action was examined. Efficiency of using different procedures for calculating a temperature increase in the friction contact under conditions of dominating elastohydrodynamic and boundary modes of lubricating action was shown. The interrelation between the processes of heat release intensity in tribotechnical contact and wear of friction pairs was established. It was analyzed that the locality of the increased wear in the central section of the contact line is determined by a change in the stress–strained surface condition at friction and by the occurrence of stress concentrator center.
Keywords
Contact Temperature, Heat Release Intensity, Boundary Layer, Lubrication Mode, Wear
To cite this article
Tareq M. A. Al-Quraan, Oksana O. Mikosyanchik, Rudolph G. Mnatsakanov, Temperature Resistance of the Boundary Lubrication Layers Under Rolling with Slippage Condition, International Journal of Mechanical Engineering and Applications. Vol. 5, No. 2, 2017, pp. 78-86. doi: 10.11648/j.ijmea.20170502.12
Copyright
Copyright © 2017 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Reference
[1]
Rymuza C. (1996) “Energy concept of the coefficient of friction”, Wear, Vol. 199, pp. 187–196.
[2]
Q. Chen, D. Y. Li, (2005) “A computational study of frictional heating and energy conversion during sliding processes”, Wear, Vol.259, pp.1382–1391.
[3]
K. Elalem, D. Y. Li, M. J. Anderson, S. Chiovelli, (2001), “Modeling abrasive wear of homogeneous and heterogeneous materials”, ASTM STP, Vol.1339, pp. 90–104.
[4]
Q. Chen, D. Y. Li. (2004) “Investigation on the mechanisms of corrosive wear process of alloy with a micro-scale dynamic model”, Mater. Sci. Eng. A, Vol.369, pp. 284–293.
[5]
V. A. Balakin, Yu. V. Lysenok (2001) “Teplovydelenie i teploperenos v zone frikcionnogo kontakta”, Vestnik GGTU im. P. O. Suhogo, № 1, S.3-7.
[6]
Balakin V. A., Galaj E. I. (2000) “Raschet prirasheniya temperatury v obode kolesa zheleznodorozhnogo podvizhnogo sostava”, Trenie i iznos, T. 21, №3, S. 269-275.
[7]
V. A. Balakin (1981) “Formation and distribution of heat in the frictional contact zone under conditions of non-stationary heat exchange”, Wear, Volume 72, Issue 2, pp 133–141. http://dx.doi.org/10.1016/0043-1648(81)90363-X.
[8]
Jahangiri M. (2014) “Investigation of the Slipping Wear based on the Rate of Entropy Generation”, Journal of Modern Processes in Manufacturing and Production, Vol. 3, No. 1, pp. 47–57.
[9]
R. Colaco, M. P. Gispert, A. P. Serrob, B. Saramago (2007) “An energy-based model for the wear of UHMWPE”, Tribol. Lett., Vol. 26, pp. 119–124.
[10]
K. E. Nurnberg, G. Nurnberg, M. Golle, H. Hoffmann (2008) “Simulation of wear on sheet metal forming tools—An energy approach”, Wear, Vol. 265, pp. 1801–1807.
[11]
A. Mihailidis, J. Retzepis, C. Salpistis, K. Panajiotidis, (1999) “Calculation of friction coefficient and temperature field of line contacts lubricated with a non-Newtonian fluid”, Wear, Vol. 232, Issue 2, pp. 213–220. http://dx.doi.org/10.1016/S0043-1648(99)00148-9.
[12]
Echávarri Otero, J., de la Guerra Ochoa, E., Chacón Tanarro, E., Díaz Lantada, A., and Munoz-Guijosa, J. M.(2016), “Analytical model for predicting friction in line contacts”, Lubrication Science, 28: 189–205. doi: 10.1002/ls.1325.
[13]
Echávarri J, Lafont P, Chacón E, de la Guerra E, Díaz A, Munoz-Guijosa JM, Muñoz JL. (2011) “Analytical model for predicting friction coefficient in point contacts with thermal elastohydrodynamic lubrication”, Proceedings IMechE Part J: Journal of Engineering Tribology, 225, pp.181–191.
[14]
Lee, S. C. and Cheng, H. S. (1992) “On the relation of load to average gap in the contact between surfaces with longitudinal roughness”, Tribology Trans., 35 (3):523-529.
[15]
Stephen M. Hsu, Richard S. Gates (2000) “Boundary Lubrication and Boundary Lubricating Films”, Chapter 12, P.484-485. DOI: 10.1201/9780849377877.ch12 – in book: Modern Trybology Hendbook. Volume One. Principles of Tribology. – Editor-in-Chief Bharat Bhushan / CRC Press, 1760p. ISBN 0-8493-84030-6/.
[16]
S. M. Hsu, M. C. Shen, E. E. Klaus, H. S. Cheng, P. I. Lacey, “Mechano-chemical model: Reaction temperatures in a concentrated contact”, Wear, Vol. 175, Issues 1–2, pp. 209-218.
[17]
T. M. A. Al-quraan, O. O. Mikosyanchik, R. G. Mnatsakanov, 2016, “The Effect of the Slippage Degree at Rolling with Slipping on the Wear Resistance of Contact Surfaces”, Mechanical Engineering Research; Vol. 6, No. 2; 2016, pp. 48–61. doi:10.5539/mer.v6n2p48.
[18]
Drozdov Yu. N., Archegov V. G., Smirnov V. I.(1981) “Protivozadirnaya stojkost trushihsya tel”, M.: Nauka, 275c.
[19]
Mikosyanchyk O., Mnatsakanov R., Zaporozhets А., Kostynik R., 2016, “Influence of the nature of boundary lubricating layers on adhesion component of friction coefficient under rolling conditions”, Eastern-European Journal of Enterprise Technologies, 4/1 (82), pp. 24-31. doi:10.15587/1729-4061.2016.75857.
[20]
E. P. Zhilnikov, V. N. Samsonov (2012) “Osnovy tribotehniki: uchebn. dlya vuzov” Samara: izd-vo Samar. gos. aerokosm. un-ta, 136s. ISBN 978-5-7883-0919-4.
[21]
Blok H., 1939,,Seizure-delayˮ method for determining the seizure protection of E. P. lubricants”, SAE J. (Trans.), Vol. 44, № 5, p.193.
[22]
Matveevskij R. M., Buyanovskij I. A., Lahshi V. L., Vipper A. B.(1976) “Ocenka energii aktivacii processa himicheskogo modificirovaniya poverhnostej treniya v usloviyah granichnoj smazki” Himiya i tehnologiya topliv i masel, №2, S. 50-52.
[23]
B. I. Kovalskij, V. G. Shram, Yu. N. Bezborodov, N. N. Malysheva, A. N. Sokolnikov (2013) “Issledovanie vliyaniya produktov temperaturnoj destrukcii na protivoiznosnye svojstva mineralnogo transmissionnogo masla TNK TRANS 80W-85GL4”,Tehnologii nefti i gaza, №2 (85), S.27-35.
[24]
Dyha A. V. (2006) “Strukturno - termodinamicheskie podhody v mehanizmah granichnogo smazyvaniya” Problemi tribologiyi (Problems of Tribology), № 3 S.62-65.
[25]
Yu. N. Bezborodov, B. I. Kovalskij, N. N. Malysheva, A. N. Sokolnikov, E. G. Malceva (2011) “Metody kontrolya i diagnostiki ekspluatacionnyh svojstv smazochnyh materialov po parametram termookislitelnoj stabilnosti i temperaturnoj stojkosti: monografiyaˮ, Krasnoyarsk:Sib.feder.un-t, 366s.
[26]
Y. O. Lyashenko, N. M. Manko (2007) “The Account of Spatial Inhomogeneity of the Temperature in the Synergetic Model of Boundary Friction”, J. Nano-Electron. Phys., Vol.5, №3, P.ІІ, 03040 (5pp.). http://jnep.sumdu.edu.ua/download/numbers/2013/3/articles/jnep_2013_V5_03040.pdf.
[27]
B. E. Gurskii, A. V. Chichinadze (2007) “Thermal friction problem and its development: Part 2. The role of heat phenomena in fracture of tooth wheels of cylindrical involute gears of real dimensions”, Journal of Friction and Wear, Vol.28, Issue 4, pp. 395-400.
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