INFLUENCE OF MECHANICAL ACTIVATION ON STRUCTURE OF COMPOSITE POWDERS BASED ON ULTRAHIGH-MOLECULAR WEIGTH POLYETHYLENE FILLED BY BORON CARBIDE

Article Sidebar

Abstract views: 119
PDF Downloads: 70
pdf (rus) (Русский)
Published: Aug 14, 2018
Keywords:
механическая активация, микроструктура, композиты, сверхвысокомолекулярный полиэтилен, карбид бора mechanical activation, microstructure, composites, ultrahigh-molecular weight polyethylene, boron carbide
Issue
No. 11 (2018)
Section
Materials Science

Main Article Content

V. ZHORNIK
The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk
S. KOVALEVA
The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk
M. BELOTSERKOVSKY
The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk
P. VITYAZ
The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk
T. GRIGORYEVA
Institute of Solid State Chemistry and Mechanochemistry of the Siberian Branch of the Russian Academy of Sciences, Novosibirsk
A. DUDAN
Polotsk State University

Abstract

 The products of mechanical alloying (MA) of a powder mixture of ultrahigh-molecular weight polyethylene and microcrystalline boron carbide (B4C) produced in the high-energy spherical planetary mill during with an energy density I = 1.1 W/g for a duration of 5 up to 25 minutes were studied by the methods of X-ray diffraction, scanning electron microscopy and FT-IR spectroscopy. It is shown that the polymeric composite particles of flake form of a size of 100…160 μm with a chaotic distribution in them of the boron carbide particles of size of 1…5 μm are formed during mechanical alloying. Oxidative degradation of the polymer is not observed. MA promotes the formation of a boron carbide structure with a lower carbon content (B6.5C). The main possible results of the interaction of the polymer matrix and dispersed filler powders in MA are the cross-linking processes with some possible decrease in its molecular weight.

Article Details

How to Cite
ZHORNIK, V., KOVALEVA, S., BELOTSERKOVSKY, M., VITYAZ, P., GRIGORYEVA, T., & DUDAN, A. (2018). INFLUENCE OF MECHANICAL ACTIVATION ON STRUCTURE OF COMPOSITE POWDERS BASED ON ULTRAHIGH-MOLECULAR WEIGTH POLYETHYLENE FILLED BY BORON CARBIDE. Vestnik of Polotsk State University. Part B. Industry. Applied Sciences, (11), 58-63. Retrieved from https://journals.psu.by/industry/article/view/497
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Author Biographies

V. ZHORNIK, The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk

д-р техн. наук

M. BELOTSERKOVSKY, The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk

д-р техн. наук

P. VITYAZ, The Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk

акад. НАН Беларуси, д-р техн. наук

T. GRIGORYEVA, Institute of Solid State Chemistry and Mechanochemistry of the Siberian Branch of the Russian Academy of Sciences, Novosibirsk

д-р хим. наук

A. DUDAN, Polotsk State University

канд. техн. наук, доц.

References

Structure, mechanical and tribological properties of radiation cross-linked ultrahigh molecular weight polyethylene and composite materials based on it. / V.V. Tcherdyntsev [et al.] // Journal of Alloys and Compounds. – 2014. – V. 586, Is. 1. – P. 443–445.

Механокомпозиты – прекурсоры для создания материалов с новыми свойствами / отв. ред. О.И. Ломовский. – Новосибирск : Изд-во СО РАН (Интеграционные проекты СО РАН, вып. 26), 2010. – 432 с.

Calculation of energy intensity and temperature of mechanoactivation process in planetary ball mill by computer simulation [Text] / E.V. Shelekhov [et al.] // Investigations and Applications of Severe Plastic Deformation ; Eds. T.C. Lowe and R.Z. Valiev ; Kluwer Academic Publishers, 2000. – Р. 139–145.

Increasing wear resistance of UHMWPE by mechanical activation and chemical modification combined with addition of nanofibers / S. Wannasri [et al.] // Procedia Engineering, 1 (2009). – P. 67–70.

Влияние механической активации сверхвысокомолекулярного полиэтилена на его механические и триботехнические свойства / В.Е. Панин [и др.] // Трение и износ. – 2010 (31). – № 2. – P. 13–19.

Iasonna, А. Power measurements during mechanical milling. An experimental way to investigate the energy transfer phenomena / А. Iasonna, M. Magini // Acta Materialia. – Vol. 44 (1996), No. 3. – P. 1109–1117.

Balzar, В. Voight-function model in diffraction line-broadening analysis / В. Balzar // Microstructure Analysis from Diffraction ; ed. by R.L. Snyder, H.J. Bunge, and J. Fiala / International Union of Crystallography, 1999.

Aselage, T.L. Lattice Constants of Boron Carbide / T.L. Aselage, R.G. Tissot // J. Am. Ceram. Soc., 75 [8] 2207–12 (1992).

ИК-спектроскопия карбида бора различной стехиометрии / Е.В. Лифшиц [и др.] // Вопросы атомной науки и техники. – 2004. – № 3. 19. Серия: Физика радиационных повреждений и радиационное материаловедение (85). – С. 19–22.

Clark, H.K. The Crystal Structure of Boron Carbide / H.K. Clark and J.L. Hoard // J. Am. Chem. Soc., 65, 2115–9 (1943).

Vast, N. Boron Carbides from First Principles / N. Vast, J. Sjakste, and E. Betranhandy // J. Phys. Conf. Ser., 176, 012002 (2009).

Kuhlmann, U. Distribution of Carbon Atoms on the Boron Carbide Structure Elements / U. Kuhlmann, H. Werheit, K.A. Schwetz // J. Alloy. Compd., 189 (1992). – P. 249–58.

Domnich, V. Chhowalla M. Boron Carbide: Structure, Properties, and Stability under Stress / V. Domnich, S. Reynaud, R.A. Haber // J. Am. Ceram. Soc., 94 [11] (2011). – P. 3605–3628.