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Consideration of Spatially Infinite Loads in the Problem for a Layer with a Cylindrical Cavity and Continuous Supports

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Publicado en:Computation vol. 13, no. 11 (2025), p. 270-289
Autor principal: Nataliia, Ukrayinets
Otros Autores: Alyoshechkina Tetyana, Miroshnikov Vitaly, Savin Oleksandr, Younis Basheer, Vynohradov Vitalii, Murahovska Olena
Publicado:
MDPI AG
Materias:
Superposition (mathematics)
Mechanical properties
Stress state
Stress-strain relationships
Cylindrical coordinates
Linear algebra
Numerical analysis
Aerospace engineering
Concentrators
Boundary conditions
Mechanical engineering
Methods
Finite element analysis
Elastic layers
Construction industry
Algorithms
Stress concentration
Structural members
Strain
Stress distribution
Composite materials
Cartesian coordinates
Acceso en línea:Citation/Abstract
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Resumen:An analytical method is proposed for determining the stress-strain state in an elastic layer with a cylindrical cavity supported by linear continuous supports perpendicular to the cavity. The need for such a development is due to the fact that in aerospace and mechanical engineering, structural elements are often affected by loads and supports described by infinite functions. This complicates the calculation for spatial bodies with complex geometry and stress concentrators. The methodology is based on the generalized Fourier method within the spatial problem of elasticity theory. The model is considered as a layer with specified stresses at the outer boundaries, where the reactions of the supports are represented as applied loads. A combined approach is used to describe the geometry using a Cartesian coordinate system for the layer and a cylindrical coordinate system for the cavity. The key idea is to decompose the original problem into two simpler ones using the principle of superposition. Auxiliary problem: the stresses in a solid layer (without a cavity) are calculated to determine the stress fields at its nominal location. Main problem: a layer with a cavity is considered, on the surface of which the stresses calculated in the first step are acting but taken with the opposite sign. The complete solution is the sum of the solutions of these two problems. Each of them is reduced to an infinite system of linear algebraic equations, which is solved by the method of reduction. This approach makes it possible to calculate the stress-strain state at any point of the body with high accuracy. Numerical analysis confirmed the correctness of satisfying the boundary conditions and showed the dependence of stresses on the nature of the distributed loads. The cylindrical cavity acts as a stress concentrator, which leads to a local increase in stresses σx and σz at the upper and lower boundaries of the layer to values that exceed both the applied load by and the calculated resistance of concrete of class C25/30.
ISSN:2079-3197
DOI:10.3390/computation13110270
Fuente:Advanced Technologies & Aerospace Database