Smart Search 


4_2019_sen_3

Title of the article

ISOTHERMAL LOCAL LOADING OF AN ELASTOPLASTIC THREE-LAYER PLATE
Authors

PLESKACHEVSKY Yuriy M., Corresponding Member of the NAS of Belarus, D. Sc. in Eng., Prof., Head of the Department “Micro and Nanotechnology”, Belarusian National Technical University, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

STAROVOITOV Eduard I., D. Sc. in Phys. and Math., Prof., Head of the Department “Structural Mechanics”, Belarusian State University of Transport, Gomel, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

LEONENKO Denis V., D. Sc. in Phys. and Math., Assoc. Prof., Professor of the Department “Structural Mechanics”, Belarusian State University of Transport, Gomel, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

In the section DYNAMICS, DURABILITY OF VEHICLES AND STRUCTURES
Year 2019 Issue 4 Pages 32–39
Type of article RAR Index UDK 539.3 Index BBK  
Abstract

The effect of circular, annular and linear uniformly distributed axisymmetric loads on a round three-layer plate with asymmetric thickness is considered. The analytical type of loads is described using the Heaviside function. The materials of the bearing layers of the plate are elastoplastic, the filler is physically nonlinear. For the asymmetric in thickness three-layer plate we have accepted the kinematic hypothesis of a broken normal. In the thin external layers the Kirchhoff’s hypotheses are accepted. The filler is no compressible through thickness. It’s normal subject to the hypothesis Timoshenko. The work of arising shear stresses is taken into account. The formulation of a boundary value problem is given. The equilibrium equations are obtained by the Lagrange variational method. Boundary conditions on the plate contour are formulated. The solution to the boundary problem is reduced to finding the three required functions: deflection, shear and radial displacements of the middle plane of the filler. For these functions, an inhomogeneous system of ordinary nonlinear differential equations is obtained. Its solution was carried out by the Ilyushin elastic solution method. It is shown that the fifth approximation can be taken as the desired solution, since its difference from the previous one does not exceed 1 %. Iterative analytical solutions are obtained in Bessel functions. Their parametric analysis is carried out. Numerical results are obtained for a plate which layers are recruited from D16T–fluoroplast-4–D16T materials which mechanical characteristics, including nonlinearity functions, were obtained earlier. The boundary conditions correspond to the hinge support of the plate contour. The influence of the physical nonlinearity of the layer materials on the displacements in the plate is investigated. It is shown that the increase in calculated displacements during elastoplastic deformation in the plate is up to 20 %.
Keywords

three-layer circular plate, circular and ring loads, elasticity, plasticity
   
Bibliography
  1. Lugovoi P.Z., Meish Yu.A. Nonstationary Deformation of Longitudinally and Transversely Reinforced Cylindrical Shells on an Elastic Foundation. International Applied Mechanics, 2016, vol. 52, no. 1, pp. 62–72.
  2. Ivañez I., Moure M.M., Garcia-Castillo S.K., Sanchez-Saez S. The oblique impact response of composite sandwich plates. Composite Structures, 2015, no. 133, pp. 1127–1136.
  3. Starovoitov E.I., Leonenko D.V., Yarovaya A.V. Vibration of circular sandwich plates under resonance loads. International Applied Mechanics, 2003, vol. 39, no. 12, pp. 1458–1463.
  4. Pleskachevsky Yu.M., Starovoitov E.I., Leonenko D.V. Dinamika krugovykh metallopolimernykh plastin na uprugom osnovanii. Chast 1. Svobodnye kolebaniya [Dynamics of circular metal-polymer plates on an elastic base. Part 1. Free oscillations]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2008, no. 4(5), pp. 48–51.
  5. Pleskachevsky Yu.M., Starovoitov E.I., Leonenko D.V. Dinamika krugovykh metallopolimernykh plastin na uprugom osnovanii. Chast II. Vynuzhdennye kolebaniya [Dynamics of circular metal-polymer plates on an elastic base. Part 1. Forced oscillations]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2009, no. 1(6), pp. 48–51.
  6. Pleskachevsky Yu.M., Kubenko V.D., Starovoitov E.I., Leonenko D.V. Kolebaniya krugovoy metallopolimernoy plastiny, svyazannoy s uprugim osnovaniem, pri teplovom udare [Vibrations of a circular metal-polymer plate connected to an elastic base under thermal shock]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2009, no. 4(9), pp. 50–54.
  7. Starovoitov E.I., Leonenko D.V. Resonant effects of local loads on circular sandwich plates on an elastic foundation. International Applied Mechanics, 2010, vol. 46, no. 1, pp. 86–93.
  8. Starovoitov E.I., Leonenko D.V., Pleskatshevsky Yu.M. Kolebaniya trekhsloynykh tsilindricheskikh obolochek v uprugoy srede Vinklera pri rezonanse [Vibrations of the three-layered cylindrical shells in the elastic Winkler’s medium at resonance]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2013, no. 4(25), pp. 70–73.
  9. Gorshkov A.G., Starovoitov E.I., Yarovaya A.V. Cyclic loading of elastic-plastic bodies in neutron flux. Mechanics of Solids, 2001, vol. 36, no. 1, pp. 64–70.
  10. Yang L., Harrysson O., West H., Cormier D. Comparison of Bending Properties for Cellular Core Sandwich Panels. Materials Sciences and Applications, 2013, vol. 4, no. 8, pp. 471–477.
  11. Lee C.R., Sun S.J., Каm Т.Y. System parameters evaluation of flexibly supported laminated composite sandwich plates. AIAA Journal, 2007, vol. 45, no. 9, pp. 2312–2322.
  12. Zenkour A.M., Alghamdi N.A. Bending Analysis of Functionally Graded Sandwich Plates under the Effect of Mechanical and Thermal Loads. Mechanics of Advanced Materials and Structures, 2010, vol. 17, no. 6, pp. 419–432.
  13. Starovoitov E.I., Yarovaya A.V., Leonenko D.V. Deformirovanie uprugogo trekhsloynogo sterzhnya lokalnymi nagruzkami [Deformation of elastic three-layer rod by local loads]. Problemy mashinostroeniya i avtomatizatsii [Engineering and automation problems], 2001, no. 4, pp. 37–40.
  14. Zhuravkov M.A., Starovoitov E.I., Leonenko D.V. Nelineynoe deformirovanie uprugoplasticheskogo trekhsloynogo sterzhnya lokalnoy nagruzkoy [The second deformation of the three-layer elastoplastic rod by local load]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2016, no. 3(36), pp. 71–79.
  15. Starovoitov E.I., Zakharchuk Yu.V. Nelineynoe deformirovanie trekhsloynoy plastiny so szhimaemym zapolnitelem [Nonlinear deformation of circular sandwich plates with compressible filler]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2019, no. 3(48), pp. 26–33.
  16. Starovoitov E.I., Leonenko D.V., Tarlakovskii D.V. Thermalforce deformation of a physically nonlinear three-layer stepped rod. Journal of Engineering Physics and Thermophysics, 2016, vol. 89, no. 6, pp. 1582–1590.
  17. Starovoitov E.I., Leonenko D.V. Deformirovanie trekhsloynogo sterzhnya v temperaturnom pole [Deformation of three-layer beam in a temperature field]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2013, no. 1(22), pp. 31–35.
  18. Starovoitov E.I., Leonenko D.V. Termouprugoe deformirovanie trekhsloynoy krugloy plastiny poverkhnostnymi nagruzkami razlichnykh form [Thermoelastic deformation of three-layer circular plate by a surface loads of various forms]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2018, no. 1(42), pp. 81–88.
  19. Starovoitov E.I., Leonenko D.V. Thermoelastic bending of a sandwich ring plate on an elastic foundation. International Applied Mechanics, 2008, vol. 44, no. 9, pp. 1032–1040.
  20. Starovoitov E.I., Leonenko D.V., Tarlakovskiy D.V. Deformirovanie trekhsloynoy krugovoy tsilindricheskoy obolochki v temperaturnom pole [Deformation of three-layer circular cylindrical shell in the thermal field]. Problemy mashinostroeniya i avtomatizatsii [Engineering and automation problems], 2016, no. 1, pp. 91–97.
  21. Starovoitov E.I., Dorovskaya E.P. Razvitie teorii rascheta sloistykh konstruktsiy [Development of the theory of calculation of layered structures]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2007, no. 1(1), pp. 48–52.
  22. Starovoitov E.I., Nagiyev F.B. Foundations of the theory of elasticity, plasticity and viscoelasticity. Toronto, New Jersey, Apple Academic Press, 2012. 346 p.
  23. Starovoitov E.I. Description of the thermomechanical properties of some structural materials. Strength of materials, 1988, vol. 20, no. 4, pp. 426–431.
  24. Starovoitov E.I. Soprotivlenie materialov [Strength of materials]. Moscow, FIZMATLIT Publ., 2008. 384 p.