How to efficiently apply soft thin coating to existing Finite Element contact model

This paper reviews several leading approaches for asymptotic modelling of thin layers in elastostatics and wave propagation phenomena. The issues related to applications of the so-called ‘equivalent’ or ‘effective’ boundary conditions and their interpretations are highlighted. Comparative analysis of asymptotic models is performed for a two-dimensional elastostatic case using a novel complex variables-based modelling tool. Its implementation allows for straightforward derivations of higher order boundary conditions for problems with layers of arbitrary sufficiently smooth curvatures. Explicit expressions for the conditions up to the third order are provided. All models are tested using available benchmark solutions and the solutions for the limiting cases of the layer parameters. This article is part of the theme issue ‘Wave generation and transmission in multi-scale complex media and structured metamaterials (part 1)’.

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“…beams, shells or plates (e.g. [1][2][3][4]), as the latter require decisions on which type of elements to use (e.g. [5]).…”

Section: Introductionmentioning

confidence: 99%

On the Bövik–Benveniste methodology and related approaches for modelling thin layers

Baranova

Mogilevskaya

2022

Phil. Trans. R. Soc. A.

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“…Double‐nodes or unfitted meshes to interfaces 11 could be another manner to discretize the solution. More recently, Tiirats et al 12 implemented a polynomial approximation to soft thin layer in Abaqus. However, the efficiency of these methods would decrease substantially as the geometry of the thin layers become more complicated, because standard FEM requires the boundaries of the elements to be aligned with the interfaces.…”

Section: Introductionmentioning

confidence: 99%

A computational approach based on extended finite element method for thin porous layers in acoustic problems

Dazel²,

Legrain

2022

Numerical Meth Engineering

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The simulation of stationary acoustic fields involving thin porous layers is addressed in the present article. Layer thickness is assumed to be relatively thin in comparison to the overall computational domain, but its non‐negligible acoustic impact must be taken into consideration in the numerical model. Within the classical finite element method (FEM), meshes are compatible at material interfaces and the element distortions needs to be avoided. These requirements usually lead to an excessively costly spatial discretization for these problems of interest, as it forces mesh refinement surrounding the thin layer. This article provides a computational approach to relax this restriction. A generalized interface model derived from the plane wave transfer matrix Method (TMM) is established for modeling thin layers. We develop variationally consistent formulations to impose the interface conditions from models of thin layers for diverse coupling configurations, in which both acoustic fluid and poro‐elastic media are taken into account. The computational domain is discretized using the extended finite element method (X‐FEM) in order to introduce strong discontinuities in elements independently of the mesh. Implementation of the proposed formulations within X‐FEM is verified to be capable of providing accurate and robust solutions. The efficiency and flexibility of the present approach for multi‐layer and complex geometry problems are demonstrated compared to classical interface‐fitted finite element models through different simulation scenarios.

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Asymptotic modeling of a reinforced plate with a thin layer of variable thickness

Mokhtari

Rahmani

2022

Meccanica

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How to efficiently apply soft thin coating to existing Finite Element contact model

Cited by 3 publications

References 24 publications

On the Bövik–Benveniste methodology and related approaches for modelling thin layers

On the Bövik–Benveniste methodology and related approaches for modelling thin layers

A computational approach based on extended finite element method for thin porous layers in acoustic problems

Asymptotic modeling of a reinforced plate with a thin layer of variable thickness

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