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On a Geometrically Non-Linear Incremental Formulation for the Modeling of 3D Concrete Printing (2021-07)

10.1016/j.mechrescom.2021.103748

 Nedjar Boumediene
Journal Article - Mechanics Research Communications, Vol. 116

Abstract

Of interest in this paper is a modeling framework when constitutive relations are given in incremental form. This is particularly true for aging concretes due to hydration. Furthermore, having in mind applications to 3D concrete printing, geometrical nonlinearities must be accounted for due to the soft nature of the fresh material. The kinematics must then be adapted adequately for a theoretically sound formulation. For this, the multiplicative split is chosen here for the deformation gradient into its known part at an earlier time and the relative deformation gradient. From the geometric point of view, this gives rise to an intermediate configuration on which incremental constitutive relations can be ideally defined prior to be transported back to the reference configuration for a Lagrangian formulation. Model examples are given for the purpose of demonstration and a set of simulations illustrate the effectiveness of the proposed framework.

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14 Citations

  1. Chen Qinbin, Barbat Gabriel, Cervera Miguel (2025-06)
    Finite Element Buildability Analysis of 3D Printed Concrete Including Failure by Elastic Buckling and Plastic Flow
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    Artificial Intelligence-Based Displacement Capacity Prediction Tool for Three-Dimensional Printed Concrete Walls
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    Study on the Ionic Transport Properties of 3D Printed Concrete
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    Numerical Simulation of Three Dimensional Concrete Printing Based on a Unified Fluid and Solid Mechanics Formulation
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    A Simple Potential Energy Formulation for 3D Concrete Printed Structures Considering the Shear Effects in the Build-Direction
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    Numerical Modelling and Simulation for Extrusion-Based 3D Concrete Printing:
    The Underlying Physics, Potential, and Challenges
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    Incremental Formulation of Early-Age Concrete in the Finite Strain Range for the Modelling of 3D Concrete Printing
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    Incremental Viscoelasticity at Finite Strains for the Modelling of 3D Concrete Printing

BibTeX 
@article{nedj.2021.OaGNLIFftMo3CP,
  author            = "Boumediene Nedjar",
  title             = "On a Geometrically Non-Linear Incremental Formulation for the Modeling of 3D Concrete Printing",
  doi               = "10.1016/j.mechrescom.2021.103748",
  year              = "2021",
  journal           = "Mechanics Research Communications",
  volume            = "116",
}
Formatted Citation

B. Nedjar, “On a Geometrically Non-Linear Incremental Formulation for the Modeling of 3D Concrete Printing”, Mechanics Research Communications, vol. 116, 2021, doi: 10.1016/j.mechrescom.2021.103748.

Nedjar, Boumediene. “On a Geometrically Non-Linear Incremental Formulation for the Modeling of 3D Concrete Printing”. Mechanics Research Communications 116 (2021). https://doi.org/10.1016/j.mechrescom.2021.103748.