Effects of Nanomodification by the Silicate Nanoparticles on Characteristics of Basalt Fibre Reinforced Polymer


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Composite material represents a complex multi-material structure consisting of coincidence array and reinforcing agent. Basalt continuous fibre and basalt composite material processing technique is one of the present day promising area. With all high characteristics of basalt fibre and basalt made products the ways of it refinement are nowhere near exhausted and one of that ways is nanomodification of the binding agents used in composite production. In this paper quoted the results of the silicate - type nanoparticle retooling influence on mechanical and physical properties of epoxianhydride binding for the purpose of lifting strength and viscoelastic properties of basalt fibre composite. It is found that the appliance of the silicate nanoparticles in epoxianhydride binding between 0.25 to 1 mass. % improve stress-related properties per 10-45%, micro plastics interlaminar shear strength increase by 25-28%, increase of dynamic modulus of elasticity - 30%, mechanical and physical properties of basalt fibre reinforced polymer based on nanomodified binder - 20%. Conducted research efforts show transmission of increased characteristics by nanomodification of epoxianhydride binding onto the characteristics of basalt fibre composite materials.



Edited by:

Dr. Denis Solovev




A.K. Kychkin and A.A. Vasilyeva, "Effects of Nanomodification by the Silicate Nanoparticles on Characteristics of Basalt Fibre Reinforced Polymer", Materials Science Forum, Vol. 945, pp. 389-394, 2019

Online since:

February 2019




[1] S.P. Bardakhanov, A. I. Korchagin, Obtaining nanoprobes by evaporation of the starting materials on an electron accelerator at atmospheric pressure. Reports of the Academy of Sciences. 3 (2006) 320-323.

[2] Adachi, T., Osaki M., Araki W., and Kwon S.C. Fracture toughness of nano- and microspherical silica-particle-filled epoxy composites. Acta Materialia. 56 (2008) 2101-2109.

DOI: https://doi.org/10.1016/j.actamat.2008.01.002

[3] Chen, C.H., Jian J. Y., and Yen F.S. Preparation and characterization of epoxy-aluminum oxide nanocomposites. Applied Science and Manufacturing. 40 (2009) 463-468.

[4] Dittanet, P., Pearson R.A. Effect of silica nanoparticle size on touheningmechanisms of filled epoxy. Polymer. 53 (9) (2012) 1890-1905.

DOI: https://doi.org/10.1016/j.polymer.2012.02.052

[5] E.A. Belyaeva, V. I. Natrusov, V.S. Osipchik, Т.Е. Shatskaya, E.S. Ananiev, A.A. Vasilyeva. Nanomodified composite for construction purposes based on epoxy anhydride binder. Nanotechnics. 4 (2012) 63-65.

[6] A.A. Vasilyeva, A.G. Tuisov, E.S. Ananieva. Development of epoxy binder with additives of nanoparticles for the manufacture of composite polymer reinforcement, in Sb. Tr. Fourteenth International Sci.-Tech. Conf. Topical. (Belokurikha, 2014). (2014) 234-237.

[7] Е.А. Belyaeva, Т.Е. Shatskaya, E.S. Ananiev, A.A. Vasil'eva. Nanomodified epoxy matrices for composite materials based on organic and mineral fibers.Fundamental Problems of Modern Materials Science. 9 (1) (2012) 119-123.

[8] A.A. Vasilyeva, Kychkin A.K. Lebedev M.P. Investigation into the properties of basalt of the Vasilevskoe deposit in Yakutia as the raw material for obtaining continuous fibers. Theoretical foundations of chemical engineering. 48 (5) (2014) 667–670.

DOI: https://doi.org/10.1134/s004057951405011x

[9] Y.A. Gorbatkina. Adhesion strength in polymer-fiber systems. M. Chemistry (1987).

[10] Y.A. Gorbatkina, V.G. Ivanova-Mumzhieva, A. M. Kuperman. Adhesion of modified epoxy matrices to reinforcing fibers. Polymer science. 58 (5) (2016) 659-666.

DOI: https://doi.org/10.1134/s0965545x16050060

[11] A.A. Kychkin, A.K. Kychkin, A.G. Tuisov. Research and Development of Combined Basalt Rods. Science and Educatoin. 4 (2015) 77-81.

[12] A.A. Vasilyeva, A.A. Kychkin, E.S. Ananieva, Lebedev M.P. Investigation of the properties of basalt of the Vasilievsky deposit of Yakutia as a raw material for obtaining continuous fibers.Chemical technology. 9 (2013) 36–44.

[13] А.N. Blaznov, Yu.P. Volkov, A.N. Lugovoi, V.F. Savin. Prediction of long-term strength of fiberglass reinforcement. Mechanics of composite materials and structures. 9 (4) (2012) 579-592.

[14] A.N. Savin, A.N. Lugovoy, Yu.P. Blaznov, A.I. Volkov, Investigation of the mechanical properties of fiberglass rods by the method of longitudinal bending. Mechanics of composite materials and structures. 10 (4) (2004) 499-516.

[15] Yu. A. Mykhailin, Fibrous Polymer Composite Materials in Engineering. St. Petersburg. Publishing house scientific foundations and technologies. (2013).