A 3D time-domain solution for the bending of viscoelastic shells

J. C. Monge; J. L. Mantari; R. M.R. Panduro

doi:10.1080/15376494.2023.2274493

A 3D time-domain solution for the bending of viscoelastic shells

J. C. Monge, J. L. Mantari, R. M.R. Panduro

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Abstract

This article presents a time domain analysis of viscoelastic doubly curved shallow shells employing 3D solution based on equilibrium equations. The constitutive equation is transformed into Laplace domain in order to avoid the time domain integration. The partial differential equations are solved for the mid-surface variables by applying the Navier Technique. The thickness equations are solved using the differential quadrature method (DQM). Lagrange interpolation polynomial are employed as basis functions. Each layer of the panel is discretized by the Chebyshev–Gauss–Lobatto grid distribution. The time-domain displacements are obtained by using the inverse Laplace transformation in an approximate numerical manner. The 3D solution is compared with references in the literature. Given the inclusion of comprehensive 3D time domain solutions, these results can be considered as a benchmark for reference.

Original language	English
Pages (from-to)	9486-9496
Number of pages	11
Journal	Mechanics of Advanced Materials and Structures
Volume	31
Issue number	27
DOIs	https://doi.org/10.1080/15376494.2023.2274493
State	Published - 2024

Keywords

Laplace transform
Navier
Shell
differential quadrature method
equilibrium equations
viscoelasticity

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10.1080/15376494.2023.2274493

Cite this

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title = "A 3D time-domain solution for the bending of viscoelastic shells",

abstract = "This article presents a time domain analysis of viscoelastic doubly curved shallow shells employing 3D solution based on equilibrium equations. The constitutive equation is transformed into Laplace domain in order to avoid the time domain integration. The partial differential equations are solved for the mid-surface variables by applying the Navier Technique. The thickness equations are solved using the differential quadrature method (DQM). Lagrange interpolation polynomial are employed as basis functions. Each layer of the panel is discretized by the Chebyshev–Gauss–Lobatto grid distribution. The time-domain displacements are obtained by using the inverse Laplace transformation in an approximate numerical manner. The 3D solution is compared with references in the literature. Given the inclusion of comprehensive 3D time domain solutions, these results can be considered as a benchmark for reference.",

keywords = "Laplace transform, Navier, Shell, differential quadrature method, equilibrium equations, viscoelasticity",

author = "Monge, {J. C.} and Mantari, {J. L.} and Panduro, {R. M.R.}",

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T1 - A 3D time-domain solution for the bending of viscoelastic shells

AU - Monge, J. C.

AU - Mantari, J. L.

AU - Panduro, R. M.R.

PY - 2024

Y1 - 2024

N2 - This article presents a time domain analysis of viscoelastic doubly curved shallow shells employing 3D solution based on equilibrium equations. The constitutive equation is transformed into Laplace domain in order to avoid the time domain integration. The partial differential equations are solved for the mid-surface variables by applying the Navier Technique. The thickness equations are solved using the differential quadrature method (DQM). Lagrange interpolation polynomial are employed as basis functions. Each layer of the panel is discretized by the Chebyshev–Gauss–Lobatto grid distribution. The time-domain displacements are obtained by using the inverse Laplace transformation in an approximate numerical manner. The 3D solution is compared with references in the literature. Given the inclusion of comprehensive 3D time domain solutions, these results can be considered as a benchmark for reference.

AB - This article presents a time domain analysis of viscoelastic doubly curved shallow shells employing 3D solution based on equilibrium equations. The constitutive equation is transformed into Laplace domain in order to avoid the time domain integration. The partial differential equations are solved for the mid-surface variables by applying the Navier Technique. The thickness equations are solved using the differential quadrature method (DQM). Lagrange interpolation polynomial are employed as basis functions. Each layer of the panel is discretized by the Chebyshev–Gauss–Lobatto grid distribution. The time-domain displacements are obtained by using the inverse Laplace transformation in an approximate numerical manner. The 3D solution is compared with references in the literature. Given the inclusion of comprehensive 3D time domain solutions, these results can be considered as a benchmark for reference.

KW - Laplace transform

KW - Navier

KW - Shell

KW - differential quadrature method

KW - equilibrium equations

KW - viscoelasticity

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JO - Mechanics of Advanced Materials and Structures

JF - Mechanics of Advanced Materials and Structures

IS - 27

ER -

A 3D time-domain solution for the bending of viscoelastic shells

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Keywords

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