employee
Bryansk, Bryansk, Russian Federation
Bryansk, Bryansk, Russian Federation
Bryansk, Bryansk, Russian Federation
UDK 631.3 Сельскохозяйственные машины и орудия. Сельскохозяйственное оборудование
Applying solid-state modelling methods for calculating the elastic properties and stress-strain state of fibre-reinforced composite materials is shown. A model of a composite material including a base and fibres is developed. The elastic properties and equivalent stresses in a fibrous composite material with different fibre content are determined.
composite, composite material, fibres, filler, elastic modulus
1. Kobelev A.G., Sharonov M.A., Kobelev O.A., Sharonova V.P. Materials Science. Technology of Composite Materials. Moscow: KNORUS, 2014. 270 p.
2. Vasiliev V.V., Protasov V.D. Composite Ma-terials. Moscow: Mashinostroenie, 1990. 512 p.
3. Galimov E.R., Tarasenko L.V., Unchikova M.V. et al. Materials Science for Transport Engineering. St. Petersburg: Lan, 2013. 443 p.
4. Dimitrienko Yu.I., Sokolov A.P. Finite Element Method for Solving Local Problems in the Mechanics of Composite Materials. Moscow: BMSTU Publ., 2010. 68 p.
5. Guryanov G.V., Kissel Yu.E. Determining the Parameters of the Electrochemical Coating Mi-crostructure by Their Dilatation. Industrial Laboratory. Materials Diagnostics, 2014, vol. 80, no. 2, pp. 33-37.
6. Kisel Y.E., Serpik I.N., Markaryants L.M., Bezik V.A., Guryanov G.V., Bezik D.A. Calculation of the Elastic Characteristics of Composite Materials with Dispersed Inclusions. International Journal of Applied Engineering Re-search, 2015, vol. 10, no. 24, pp. 44018-44022.
7. Perov S.N., Chernyakin S.A. Studying the Applicability of the Finite Element Method for Assessing the Fracture Mechanics Parameters of Structural Elements Made of Composite Materi-als. Izvestiya of Samara Scientific Centre of the Russian Academy of Sciences, 2013, vol. 15, no. 4-2, pp. 480-483.
8. Kotovich A.V., Stankevich I.V. Solution of Thermal Conductivity Problems by the Finite Element Method. Moscow: BMSTU Publ., 2012. 112 p.
9. Fujii T., Dzako M. Fracture Mechanics of Composite Materials. Moscow: Mir, 1982. 232 p.
10. Kisel, Yu.E. Improving the Durability of Ag-ricultural Machinery Parts by Electrothermal Treatment of Composite Electrochemical Coatings. Doct. Diss. Saratov State Vavilov Agrarian University. Saratov, 2014.
11. Kapitonov A.M., Redkin V.E. Physical and Mechanical Properties of Composite Materials. Elastic Characteristics. Krasnoyarsk: Siberian Federal University Publ., 2013. 532 p.
12. Shimkovich D.A. Calculation of Structures in MSC/NASTRAN for Windows. Moscow: DMK Press Publ., 2001. 448 p.
13. Silman, G.I. Structural Steels. Recommendations on Choosing Steel Grade and Type of its Thermal and Chemical-Thermal Treatment for Machine Parts and Structures. Bryansk: Bryansk State Engineering and Technology Academy, 1999. 70 p.
14. Guryanov G.V., Kissel Yu.E. Determining the Parameters of the Electrochemical Coating Mi-crostructure by Their Dilatation. Zavodskaya laboratoriya. Diagnostika materialov [Industrial Laboratory. Materials Diagnostics], 2014, vol. 80, no. 2, pp. 33-37.
15. Hayashi T. Composite Materials. Nika Giren, 1971. 85 p.
