Finite Element Formulations for Beam-to-Solid Interaction – From Embedded Fibers Towards Contact

07/23/2021

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Contact and related phenomena, such as friction, wear or elastohydrodynamic lubrication, remain as one of the most challenging problem classes in nonlinear solid and structural mechanics. In the context of their computational treatment with finite element methods (FEM) or isogeometric analysis (IGA), the inherent non-smoothness of contact conditions, the design of robust discretization approaches as well as the implementation of efficient solution schemes seem to provide a never ending source of hard nuts to crack. This is particularly true for the case of beam-to-solid interaction with its mixed-dimensional 1D-3D contact models. Therefore, this contribution gives an overview of current steps being taken, starting from state-of-the-art beam-to-beam (1D) and solid-to-solid (3D) contact algorithms, towards a truly general 1D-3D beam-to-solid contact formulation.

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Finite Element Formulations for Beam-to-Solid Interaction – From Embedded Fibers Towards Contact

Extended Comment on the Article "Consistent Development of a Beam-To-Beam Contact Algorithm via the Curve to Solid Beam Contact - Analysis for the Non-Frictional Case"

Hybrid high-order methods. A primer with application to solid mechanics

A robust and scalable unfitted adaptive finite element framework for nonlinear solid mechanics

Asymptotically consistent and computationally efficient modeling of short-ranged molecular interactions between curved slender fibers undergoing large 3D deformations

Analytical shape determination of fiber-like objects with Virtual Image Correlation

Continuous gap contact formulation based on the screened Poisson equation

Consistent coupling of positions and rotations for embedding 1D Cosserat beams into 3D solid volumes

Finite Element Formulations for Beam-to-Solid Interaction – From Embedded Fibers Towards Contact

Related Research

Extended Comment on the Article "Consistent Development of a Beam-To-Beam Contact Algorithm via the Curve to Solid Beam Contact - Analysis for the Non-Frictional Case"

Hybrid high-order methods. A primer with application to solid mechanics

A robust and scalable unfitted adaptive finite element framework for nonlinear solid mechanics

Asymptotically consistent and computationally efficient modeling of short-ranged molecular interactions between curved slender fibers undergoing large 3D deformations

Analytical shape determination of fiber-like objects with Virtual Image Correlation

Continuous gap contact formulation based on the screened Poisson equation

Consistent coupling of positions and rotations for embedding 1D Cosserat beams into 3D solid volumes