Rheological behavior and fatigue of aluminum oxide - based composite structures on soft substrates

• Autorzy: Kireitseu M.
• Języki publikacji: EN

Abstrakty

EN

The present paper describes rheological behavior and fatigue of novel composite systems "chrome carbide - aluminum oxide - aluminum" and "steel - soft polymer - aluminum - aluminum oxide". Rheological models of the composite systems have been proposed and confirmed by in-situ experiments at Hertzian indentation. Load rating tests revealed ultimate stresses and stress-deformation modes of the systems. A possibility has been demonstrated of improving mechanical properties of aluminum oxide-based layers by CrC nanoparticles deposited by the metalorganic chemical vapor deposition. The CrC nanoparticles fill various surface defects of the aluminum oxide thus strengthening and toughening the system. High fracture resistance has been observed.

Słowa kluczowe

EN

rheology; composite; aluminum oxide; fracture; mechanics

PL

mechanika; reologia; pęknięcia

• Wydawca: Oficyna Wydawnicza Uniwersytetu Zielonogórskiego
• Czasopismo: International Journal of Applied Mechanics and Engineering
• Rocznik: 2003
• Tom: Vol. 8, no. 2
• Strony: 252--270
• Opis fizyczny: Bibliogr. 47 poz., wykr.

Twórcy

autor

Kireitseu M.

• Institute of Machine Reliability (INDMASH NAS of Belarus) National Academy of Sciences of Belarus, Lesnoe 19-62, Minsk 223052, BELARUS

Bibliografia

• [1] An L. (1996): Fracture and Contact Damage Behavior of Some Oxide Aluminum-based Ceramic Composites. - Ph.D. Dissertation, Lehigh University, Bethlehem, PA.
• [2] Andrievsky R. and Spivak I. (1989): Strength of Refractory Compounds and Materials. - Moscow: Metallurgia.
• [3] Ashby M. and Hallam S. (1986): The failure of brittle solids containing small cracks under compressive stress states. - Acta Metal., vol.34, No.3, pp.497-510.
• [4] Basenuk V., Kireytsev M. and Fedaravichus A. (2001): Application of rheological models to composite sliding bearings based on polymer-metal-ceramics composition. - Proc. of the Symposium of Material and Construction Failure, May 23-25, 2001, Augustov, Poland, pp.12-13.
• [5] Bezuhov N.P. (1968): Fundamentals of Elasticity, Plasticity and Flow Theories. - Moscow: Vishaya Shkola.
• [6] Cai H., Kalceff M.A.S. and Lawn B.R. (1994): Deformation and fracture of mica-containing glass-ceramics in hertzian contact. - J. Mater. Res., vol.9, No.3, pp.762-770.
• [7] Cho S., Moon H., Hockey B.J. and Hsu S.M. (1992): The transition from mild to severe wear in oxide aluminum during sliding. - Acta Metal., vol.40, pp.185-192.
• [8] Collins J. (1993): Failure of Materials in Mechanical Design. - N.Y.: John Wiley and Sons, 2nd Edition.
• [9] Dorner F. and Nix W.D. (1992): Method for interpreting data from depth sensing intentation instruments. - J. Mat. Res., vol. 1, pp.601-609.
• [10] Frank C. and Lawn B.R. (1967): On the theory of Hertzian fracture. - Proc. R. Soc. London, vol.A299, pp.291-306.
• [11] Golberg D.I. (1970): Mechanical Behavior of Polymers. - Moscow: Chemistry.
• [12] Guiberteau S.F., Padlure N.P. and Lawn B.R. (1994): Effect of grain size on hertzian contact in oxide aluminum. - J. Am. Ceram. Soc., vol.77, pp.1825-1831.
• [13] Gul V.E. (1971): Structure and Strength of Polymers. - Moscow: Nauka.
• [14] Hertz H. (1985): Uber die Beruhrung fester elastischer Korper. - Leipzig: Gessamelte Werke, Bd.l.
• [15] Hioki A.I., Nada S., Doi H., Katamoto J. and Kamogoito O. (1989): Deposition techniques of hard coatings. - Nucl. Instrum. Methods Phys. Res., vol.39, pp.657-662.
• [16] Huber M.T. (1904): Zur Theorie der Beruhrung Fester Elasticher Korper. - Ann. Phys. (Leipzig), vol.43, No.61, pp. 153-163.
• [17] Izraelian A.M. (1940): Mechanical Tests of Resin, Ebonite and Plastics. - Moscow: Nauka.
• [18] Kireytsev M. (2001): Mechanical properties of composite layers based on hard anodic oxide ceramics. - Proc. of the SEM Annual Conference and Exposition, Best Student Paper Competition, June 4-6, 2001, Portland, Oregon, USA, pp.12-13.
• [19] Kireytsev M. and Basenuk V. (2001a): Investigation of tribological properties of the CrC-Al203-Al. - Proc. of 2nd Int. Symposium on Modeling the Performance of Engineering Structural Materials (MPESM-II), TMS-2001, November, Indianapolis, USA, pp.342-346.
• [20] Kireytsev M. and Basenuk V. (2001b). Study of load rating of the CrC-Al203-Al composite layer. - Proc. of 2nd Int. Symposium on Modeling the Performance of Engineering structural Materials (MPESM-II), TMS-2001, November, Indianapolis, USA,pp.124-127.
• [21] Kireitseu M., Yerakhavets S., Basenuk V. And Belotserkovski M. (2002a): Composite bearing based on metal - polymer - soft metal - ceramics. - Proc. of 104th Annual Meeting and Exposition of the American Ceramic Society (G. Ginger, Ed.), St. Louis, Missouri, USA, April 29 - May 3, 2002, pp.154-162.
• [22] Kireitseu M., Nemerenco I., Yerakhavets L.V. and Beltsova K. (2002b): Nanoindentation of alumina-chrome carbide and alumina-ultra dispersed diamonds composite coatings. - Proc. of Modeling the Performance of Engineering Structural Materials III (D.R. Lesuer, T.S. Srivatsan, and E.M. Taleff, Eds.) TMS-2002, November, IN, USA. pp.269-277.
• [23] Kireitseu M.V., Nemerenco I, Yerakhavets L.V. and Beltsova K. (2002c): Hard oxide ceramics modified by ultra disperced diamonds. - Proc. of Modeling the Performance of Engineering Structural Materials III (D.R. Lesuer, T.S. Srivatsan and E.M. Taleff, Eds.) TMS-2002, November, IN, USA. pp.279-288
• [24] Laugier M.T. (1984): Hertzian fracture of sintered oxide aluminum. - J. Mater. Sciences, vol. 19, pp.254-258.
• [25] Lawn B.R. (1968): Hertzian fracture in single crystals with the diamond structure. - J. Appl. Phys., vol.39, pp.4828-4836.
• [26] Lawn B.R. (1993): Fracture of Brittle Solids. - Cambridge, U.K.: Cambridge University Press.
• [27] Lawn B.R. (1998): Indentation of ceramics with spheres: A century after Hertz. - J. Am. Ceram. Soc., vol.81, No.9, pp.394-404.
• [28] Lawn B.R., Padture N.P., Cai H., and Guiberteau F. (1994): Making ceramics ductile. - Science, vol.263, pp. 1114-1116.
• [29] Markov G.A. (1992): Micro arc oxidizing. - Vestnik of Moscow St. Univ., Mashinostroenie, No.l, pp.32-45.
• [30] Mott B.W. (1956): Micro Indentation Hardness Testing. - London: Butterworth’s.
• [31] Padture N.P. and Lawn B.R. (1995). Contact fatigue of a silicon carbide with a heterogeneous grain structure. - J. Am. Ceram. Soc., vol.78, No.6, pp.1431-1438.
• [32] Patel J.L. and Nannaji S. (2000): A New Layer Process for Aluminum. - Microplasmic Corp., Peabody, Mass. http://www.microplasmic.com.
• [33] Pelhica J.B., Hutchings R. and Oliver W.C. (1983): Hardness measurements at penetration depth as small 20nm. - Phil. Magazine, vol.48, pp.593-606.
• [34] Pharr G.M., Harding D.S., Oliver W.C. (1993): Mechanical Properties and Deformation Behaviour of Materials Having Ultra-Fine Microstructures, In: Mechanical Properties of Composites (M. Nastasi, Ed.) - Kluwer, Netherlands, pp.449-461.
• [35] Rebinder P.A. (1958): Physic-chemical Mechanics. - Moscow: Nauka.
• [36] Reiner M. (1965): Rheology. - Moscow: Nauka.
• [37] Reiner M. (1963): Deformation and Flow. - Moscow: Nauka.
• [38] Russian Federation Patent on Invention No.2.175.686.: Composite layer and its manufacturing technology. - InternT Class C23 C28/00, Berestnev O.V., Basenuk V.L., Kireitseu M.V., Makarevich G.V. and Sosnovski A.A., Appl. No.2000111046/02, date November 10, 1999, Accepted April 12, 2000, Izobretenia, 2000, No.20, pp.l 12.
• [39] Rudnitski V.A., Kren A.P. and Shilko S.V. (2001): Rating the behavior of elestomers by their indentation at constant rates. - Wear, vol.22, No.5, Sept.-Oct. 2001, pp.502-508.
• [40] Shelley T. (1998): Showing the hard face of light metals. - Technical Feature Magazine, Materials, No.6, New Ideas in Technology, Eureka Press., pp. 13-18.
• [41] Shulman Z.P., Smolski G.P and Zaltzgender V.I. (1977): Rheophysics. - Minsk: Nauka.
• [42] Shulman Z.P. and Smolski B.S. (1978): Rheological Behaviour of the Composite Systems and Structures. - Minsk: Nauka.
• [43] Smolski B.S. and Shulman Z.P. (1970): Rheodynamic of Non-linear Viscous-plastic Materials. - Minsk: Nauka.
• [44] Swarts W., Linn J., Ammons J. and Kovac M. (1984): Mechanical behaviour of fiber-glasses alumina. - Thin Solid Films, vol. 114, pp.349-357.
• [45] Tillett J.P. (1956): Fracture of glass by spherical indenters. - Proc. Ph’s. Soc. London, vol.8, No.869, pp.981-992.
• [46] Tustison R., Varitimos T., Montanari D. and Wahl J. (1989): Fracture and fatigue of textured alumina composites. - J. Vac. Sci. Technol., vol.A7, pp.2256-2265.
• [47] Wiktoreks S. (1986): Studies of physical properties of hot sprayed aluminum metal coatings to steel substrates. - Corrosion, vol.33, pp.4-9.