Elliptic boundary layer in shells of revolution under surface shock loading of normal type

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This article presents a method for solving the boundary-value problem for an elliptic boundary layer occurring in thin-walled shells of revolution under impact loads of normal type applied to the face surfaces. The elliptic boundary layer is formed in the vicinity of the conditional front of Rayleigh surface waves and is described by elliptic equations with boundary conditions determined by hyperbolic equations. In the general case of shells of revolution, methods for solving elliptic boundary layer equations developed for shells of revolution with zero Gaussian curvature cannot be applied. The previously considered approach using Laplace and Fourier integral transforms fails because the governing equations become equations with variable coefficients. The method proposed in this article for solving the equations of the elliptic boundary layer is based on the use of asymptotic representations of the Laplace-transformed solutions (in time) in exponential form. Numerical calculations of normal stresses based on the obtained analytical solutions are provided for the case of a spherical shell.

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Sobre autores

I. Kirillova

Saratov State University

Autor responsável pela correspondência
Email: nano-bio@info.sgu.ru
Rússia, Saratov

Bibliografia

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  8. Kirillova I.V., Kossovich L.Y. Asymptotic theory of wave processes in shells of revolution under surface impact and normal end actions Mechanics of Solids. 2022. Т. 57. № 2. P. 232–243.
  9. Kirillova I.V., Kossovich L.Y. refined equations of elliptic boundary layer in shells of revolution under normal shock surface loading. Vestnik of the St. Petersburg University: Mathematics. 2017. Т. 50. № 1. С. 68–73.
  10. Kaplunov Yu.D., Kossovich L.Yu. Asymptotic model for calculating the far field of a Rayleigh wave in the case of an elastic half-plane. Reports of the Academy of Sciences. 2004. Vol. 395. No. 4. Pp. 482–484.
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2. Fig. 1. Semi-infinite shell of rotation.

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3. Fig. 2. Cross-sectional geometry of a spherical shell.

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4. Fig. 3. Plot of normal stress 33 in the small neighborhood of the Rayleigh wave front at time for values of the normal coordinate.

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