Investigation of Structure and Physico-Mechanical Properties of Composite Materials Based on Copper - Carbon Nanoparticles Powder Systems

• Autorzy: Kovtun V. , Pasovets V. , Pieczonka T.

Identyfikatory

DOI

10.1515/amm-2015-0008

Warianty tytułu

PL

Badanie struktury i właściwości fizyko-mechanicznych spiekanych materiałów kompozytowych miedź-nanocząstki węgla

• Języki publikacji: EN

Abstrakty

EN

Physico-mechanical and structural properties of electrocontact sintered copper matrix- carbon nanoparticles composite powder materials are presented. Scanning electron microscopy revealed the influence of preliminary mechanical activation of the powder system on distribution of carbon nanoparticles in the metal matrix. Mechanical activation ensures mechanical bonding of nanoparticles to the surface of metal particles, thus giving a possibility for manufacture of a composite with high physico-mechanical properties.

PL

Materiały kompozytowe o osnowie miedzi zawierające nanocząstki węgla wytwarzano metodą spiekania elektrostyko-wego. Spieki poddano badaniom właściwości fizyko-mechanicznych oraz badaniom strukturalnym. Obserwacje przełomów za pomocą mikroskopu skaningowego wykazały korzystny wpływ mechanicznej aktywacji mieszanki proszków na rozmieszczenie nanocząstek węgla w osnowie metalowej. Aktywacja prowadzona w wysokoenergetycznym młynie wibracyjnym doprowadza do mechanicznego połączenia nanocząstek węgla z powierzchnią cząstek miedzi, dzięki czemu możliwe jest wytworzenie spiekanego kompozytu o wysokich właściwościach fizyko-mechanicznych.

Słowa kluczowe

EN

powder metallurgy; electrocontact sintering; physico-mechanical properties; carbon nanoparticles; composite powder materials; triboengineering characteristics; mechanical activation

PL

metalurgia proszków; spiekanie elektrostykowe; właściwości fizykomechaniczne; nanocząstki węgla; kompozytowe materiały proszkowe; aktywacja mechaniczna

• Wydawca: Institute of Metallurgy and Materials Science of Polish Academy of Sciences ; Committee of Materials Engineering and Metallurgy of Polish Academy of Sciences
• Czasopismo: Archives of Metallurgy and Materials
• Rocznik: 2015
• Tom: Vol. 60, iss. 1
• Strony: 51--55
• Opis fizyczny: Bibliogr. 23 poz., rys., tab.

Twórcy

autor

Kovtun V.

• State Educational Establishment “Gomel Engineering Institute” of The Ministry for Emergency Situations of The Republic of Belarus, Gomel, Belarus

autor

Pasovets V.

• State Educational Establishment “Gomel Engineering Institute” of The Ministry for Emergency Situations of The Republic of Belarus, Gomel, Belarus

autor

Pieczonka T.

• AGH University of Science and Technology, Al. A. Mickiewicza 30, 30-059 Kraków, Poland

Bibliografia

• [1] D. M. Karpinos, L. I. Tuchinsky, and L. R. Vishnyakov, Novel Composite Materials, Kiev, Vishcha Shkola, 1977.
• [2] V. A. Belyi, Problems in Developing Composite Materials and Control of Their Frictional Properties, J. Friction and Wear 3, 3, 389-395 (1982).
• [3] N. M. Rusin, A. P. Savitsky, A. A. Bataev, Graphite Effect on Triboengineering Properties of Sintered Alloys od Al-Ti System, J. Friction and Wear 19, 5, 628-632 (1998).
• [4] V. A. Vereshchagin, V. V. Zhuravlev, Composite Diamond-Containing Materials and Coatings, Minsk, Nauka i Tekhnika, 1981.
• [5] Catalogue of Diamond Goods Produced in Republic Belarus, Ed. By PA. Vityaz’, A.F. Iliyushenko, E.V. Zvonarev, Minsk, Tonpik, 2005.
• [6] T. Cabioch, E. Thune, J. P. Riviere, et al., Structure and Properties of Carbon Onion Layers Deposited onto Various Sub- strates, J. Appl. Phys. 91, 3, 1560-1567 (2002).
• [7] S. R. Cohen, Y. Feldman, H. Cohen, et al., Nanotribology of Novel Metal Dichalcogenide, J. Appl. Surf. Sci, 603-607 (1999).
• [8] X. H. Chen, J. C. Peng, X. Q. Li, et al., Tribological Behavior of Carbon Nanotubes-Reinforced Nickel Matrix Composite Coatings, J. Mater. Sci. Lett. 20, 22, 2057-2060 (2001).
• [9] M. Damnjanovic, T. Vukovic, and I. Milosevic, Super-Slippery Carbon Nanotubes. Symmetry Breaking Breaks Friction, Eur. Phys. J. 25, 2, 131-134 (2002).
• [10] V. A. Kovtun, V. N. Pasovets, Carbon Nanostructures: Properties and Promises for Using in Powder Composite Materials of Tri-boengineering Purposes, J. Friction and Wear 27, 2, 206-215 (2006).
• [11] N. Kobayasi, Introduction into nanotechnology, Tran. From Japanese, Ed. By Prof. Patrikeeva L.N., Moscow, BINOM, Knowledge Laboratory, 2005.
• [12] M. Ratner, D. Ratner, Nanotechnology: Simple Explanation to a Next Genius Idea, Transl. From English, Moscow, Publ. House Williams, 2004.
• [13] A. D. Pomogailo, A. S. Rozenberg, I. E. Uflyand, Metal nanopar-ticles in Polymers, Moscow, Khimiya, 2000.
• [14] Nanomaterials: Synthesis, Properties and Applications, Ed. by A. S. Edelstein, C. Cammarata, Institute of Physics, Bristol and Philadelphia, 1996.
• [15] L. S. Pinchuk, V. A. Struk, N. K. Myshkin, A. I. Sviridenok, Materials science and Structural Materials, Ed. By Acad. Belyi V.A., Minsk, Vysheishaya Shkola, 1989.
• [16] E. Dujardin, T. W. Ebbesen, H. Hiura, K. Tanigaki, Capillarity and Wetting of Carbon Nanotubes, Science 265, 1850-1856 (1994).
• [17] T. W. Ebbesen, H. Hiura, M. E. Bisher, et al., Decoration of Carbon Nanotubes, Advanced Materials 8, 155-167 (1996).
• [18] A. I. Raichenko, Bases of Sintering Process of Powders by Passing Electric Current, Moscow, Metallurgiya, 1987.
• [19] L. S. Vasiliev, I. L. Lomaev, On Probable Mechanisms of Evo-lution of Nanostructures at Intensive Plastic Deformation of Metals and Alloys, FMM 101, 4, 417-424 (2006).
• [20] S. F. Lomaeva, On the Mechanisms of Formation of Dispersi-ty and Structural-Phase Composition in Iron-based Systems at Mechanical Activation, Deformation and Failure of Materials, 3, 9-15 (2005).
• [21] A. A. Stefanovich, P. A. Vityaz, B. B. Khina, Structural-Phase Transformations and Mass-Transfer in Mechanically Alloyed Compositions, Powder Metallurgy, 23, 85-90 (2000).
• [22] J. Goldstein, D. Newberry, P. Achlin, et al., Scanning Electron Microscopy and X-ray Analyzer, Moscow, Mir, 1984.
• [23] F. A. Gimelfarb, and S. L. Shvartsman, Contemporary Meth-ods of Control of Composite Materials, Moscow, Metallurgiya, 1979.