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17-03-2024 | Original Article

A moment–curvature-based constitutive model for interactive simulation of visco-plastic rods

Authors: Karthikeyan Panneerselvam, Suvranu De

Published in: Engineering with Computers | Issue 5/2024

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Abstract

A moment–curvature constitutive model is proposed for the dynamic simulation of visco-plastic rods subject to time-varying loads and constraints at interactive rates. Smooth spline functions are used to discretize the geometry of the rod and its kinematics with the centerline coordinates as degrees of freedom (DOF) and scalar twist as degrees of freedom (DOF). The plastic curvature is defined as a uniformly varying field in contrast to localized lumped plasticity models, suitable for simulation of spatial rods that undergo uniform plastic deformation such as a cable or surgical suture thread. The yield criterion and plastic/visco-plastic flow rule are developed for spatial rods taking advantage of the availability of smooth moment–curvature fields using the spline-based formulation. With the Bishop frame field as a reference, the material curvatures are quantified using the twist degree of freedom, enabling tracking the plastic fields with scalar twist, thereby eliminating slopes as DOF. Taking advantage of the invariant sub-blocks and the sparsity of the dynamic system matrix arising from the numerical discretization, an hierarchical (H-matrix) solution approach is utilized for efficient computation. Uniform curvature bending tests and moment relaxation tests are performed to study the convergence behavior of the model. Several real-world tests involving contact are performed to demonstrate the applicability of the model in interactive simulations.

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Title: A moment–curvature-based constitutive model for interactive simulation of visco-plastic rods
Authors: Karthikeyan Panneerselvam
Suvranu De
Publication date: 17-03-2024
Publisher: Springer London
Published in: Engineering with Computers / Issue 5/2024
Print ISSN: 0177-0667
Electronic ISSN: 1435-5663
DOI: https://doi.org/10.1007/s00366-023-01938-0

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Abstract

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Springer Professional "Technik"

Springer Professional "Wirtschaft+Technik"

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qRLS: quantum relaxation for linear systems in finite element analysis

Performance evaluation of deep learning approaches for predicting mechanical fields in composites

The Trefftz methods for 3D biharmonic equation using directors and in-plane biharmonic functions

Image-based biomarkers for engineering neuroblastoma patient-specific computational models

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