Abstract
The formulation of the acoustoelasticity problem is given on the basis of refined motion equations of orthotropic plates. These equations are constructed in the first approximation by reducing the three-dimensional equations of the theory of elasticity to the two-dimensional equations of the theory of plates, where the approximation of the transverse tangential stresses and the transverse reduction stress is made with the help of trigonometric basis functions in the thickness direction. Wherein at the points of the boundary (front) surfaces, the static boundary conditions of the problem for tangential stresses are satisfied exactly and for transverse normal stress — approximately. Accounting for internal energy dissipation in the plate material is based on the Thompson—Kelvin—Voigt hysteresis model. In case of formulating problems on dynamic processes of plate deformation in vacuum, the equations are divided into two separate systems of equations. The first of these systems describes non-classical shear-free, longitudinal-transverse forms of movement, accompanied by a distortion of the flat form of cross sections, and the second system describes transverse bending-shear forms of movement. The latter are practically equivalent in quality and content to the analogous equations of the well-known variants of refined theories, but, unlike them, with a decrease in the relative thickness parameter, they lead to solutions according to the classical theory of plates. The motion of the surrounding the plate acoustic media is described by the generalized Helmholtz wave equations, constructed with account of energy dissipation by introducing into consideration the complex sound velocity according to Skudrzyk.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Paimushin, V.N., Gazizullin, R.K. “Static and Monoharmonic Acoustic Impact on a Laminated Plate”, Mechanics of Composite Materials 53 (3), 283–304 (2017).
Paimushin, V.N., Tarlakovskii, D.V., Gazizullin, R.K., Lukashevich, A. “Investigation of different versions of formulation of the problem of soundproofing of rectangular plates surrounded with acoustic media”, J. Math. Sci. 220 (1), 59–81 (2017).
Paimushin, V.N., Gazizullin, R.K., Sharapov, A.A. “Numerical and Experimental Study of the Sound-Insulating Properties of a Deformable Plate Located between Two Chambers”, Proc. Engineering 106, 336–349 (2015).
Ambartsumyan, S.A. Theory of anisotropic plates: Strength, Stability, and Vibrations (Nauka, Moscow, 1987) [in Russian].
Bolotin, V.V., Novichkov, Yu.N. Mechanics of multilayer constructions (Mashinostroyenie, Moscow, 1980) [in Russian].
Pelekh, B.L. Theory of shells with finite shear stiffness (Nauk. dumka, Kiev, 1973) [in Russian].
Ricards, R.B., Teters, G.A. Stability of shells made of composite materials (Zinatne, Riga, 1974) [in Russian].
Vekua, I.N. Some general methods of constructing different variants of shell theory (Nauka, Moscow, 1982) [in Russian].
Gorynin, G.L., Nemirovskiy, Yu.V. Spatial Problems of Bending and Twisting the Layered Constructions. Method of Asymptotic Splitting (Nauka, Novosibirsk, 2004) [in Russian].
Grigolyuk, E.I., Seleznev, I.T. Non-classical theory of vibrations of rods, plates and shells. Itogi Nauki i Tekhniki. Ser. mekh. tverdykh deform. tel. V. 5 (VINITI, Moscow, 1973) [in Russian].
Altenbakh, Kh. “The main directions of the theory of multilayer thin-walled structures”, Mechanics of Composite Materials 34 (6), 333–348 (1998) [in Russian].
Paimushin, V.N. “Exact and approximate analytical solutions to a problem on plane modes of free oscillations of a rectangular orthotropic plate with free edges, with the use of trigonometric basis functions”, Mechanics of Composite Materials 41 (4), 313–332 (2005).
Paimushin, V.N. “Exact analytic solutions of the problem of the plane forms of free oscillations of a rectangular plate with free edges”, Russian Math. (Iz. VUZ) 50 (8), 50–58 (2006).
Paimushin, V.N., Polyakova, T.V. “Exact analytic solutions to the three-dimensional problem of free vibrations of an orthotropic rectangular parallelepiped with free faces”, Mechanics of composite materials and structures 12 (3), 317–336 (2006) [in Russian].
Paimushin, V.N., Polyakova, T.V. “Exact and approximated equations of statics and dynamics of a rodstrip and generalized classical models”, Mechanics of composite materials and structures 14 (1), 126–156 (2008) [in Russian].
Paimushin, V.N., Polyakova, T.V. “The small free oscillations of a strip”, J. Appl. Math. and Mechan. 75 (1), 49–55 (2011).
Ivanov, V.A., Paimushin, V.N., Polyakova, T.V. “Study of the stress-strain state of a rod-strip based on the equations of flat problem of elasticity theory and new variant of refined theory of rods”, Mechanics of composite materials and structures 14 (3), 373–388 (2008) [in Russian].
Skudrzyk, E. The foundations of acoustics (Springer-Verlag, Wien — New York, 1971).
Funding
The work was performed under financial support of Russian Science Foundation (project no. 19-19-00058).
Author information
Authors and Affiliations
Corresponding authors
Additional information
Russian Text © The Author(s), 2020, published in Izvestiya Vysshikh Uchebnykh Zavedenii. Matematika, 2020, No. 5, pp. 62–73.
About this article
Cite this article
Paimushin, V.N., Polyakova, T.V., Polyakova, N.V. et al. Refined Orthotropic Plate Motion Equations for Acoustoelasticity Problem Statement. Russ Math. 64, 56–65 (2020). https://doi.org/10.3103/S1066369X20050060
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.3103/S1066369X20050060