Modelling size-dependent bending, buckling and vibrations of 2D triangular lattices by strain gradient elasticity models: Applications to sandwich beams and auxetics

Khakalo, Sergei; Balobanov, Viacheslav; Niiranen, Jarkko

doi:10.1016/j.ijengsci.2018.02.004

Cited by 155 publications

(77 citation statements)

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“…On the other hand, the rigorous considerations will need to be supported also with heuristic considerations. In this aspect, the method of numerical homogenisation can be of use, see Giorgio and Khakalo et al It has to be remarked that the numerical study of higher gradient continuum models is not so easy and requires some nontrivial improvements of the standard methods. We have found particularly interesting, in the context of the investigations presented here, the results found in the previous studies …”

Section: Closing Remarks and Future Challengessupporting

confidence: 77%

A nonlinear Lagrangian particle model for grains assemblies including grain relative rotations

Turco

Dell’Isola²,

Misra

2019

Num Anal Meth Geomechanics

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Summary We formulate a discrete Lagrangian model for a set of interacting grains, which is purely elastic. The considered degrees of freedom for each grain include placement of barycenter and rotation. Further, we limit the study to the case of planar systems. A representative grain radius is introduced to express the deformation energy to be associated to relative displacements and rotations of interacting grains. We distinguish inter‐grains elongation/compression energy from inter‐grains shear and rotations energies, and we consider an exact finite kinematics in which grain rotations are independent of grain displacements. The equilibrium configurations of the grain assembly are calculated by minimization of deformation energy for selected imposed displacements and rotations at the boundaries. Behaviours of grain assemblies arranged in regular patterns, without and with defects, and similar mechanical properties are simulated. The values of shear, rotation, and compression elastic moduli are varied to investigate the shapes and thicknesses of the layers where deformation energy, relative displacement, and rotations are concentrated. It is found that these concentration bands are close to the boundaries and in correspondence of grain voids. The obtained results question the possibility of introducing a first gradient continuum models for granular media and justify the development of both numerical and theoretical methods for including frictional, plasticity, and damage phenomena in the proposed model.

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Section: Closing Remarks and Future Challengessupporting

confidence: 77%

A nonlinear Lagrangian particle model for grains assemblies including grain relative rotations

Turco

Dell’Isola²,

Misra

2019

Num Anal Meth Geomechanics

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“…The approach may also be applicable in the context of other nonclassical continuum mechanics theories [see, e.g. (Khakalo et al, 2018)]. We note that there are different strategies to obtain the periodic, classical 3-D stresses of a web-core sandwich panel by post-processing the 2-D micropolar results.…”

Section: Discussionmentioning

confidence: 99%

Two-scale micropolar plate model for web-core sandwich panels

Karttunen

Reddy

Romanoff

2019

International Journal of Solids and Structures

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A 2-D micropolar equivalent single-layer (ESL), first-order shear deformation (FSDT) plate model for 3-D web-core sandwich panels is developed. First, a 3-D web-core unit cell is modeled by classical shell finite elements. A discrete-to-continuum transformation is applied to the microscale unit cell and its strain and kinetic energy densities are expressed in terms of the macroscale 2-D plate kinematics. The hyperelastic constitutive relations and the equations of motion (via Hamilton's principle) for the plate are derived by assuming energy equivalence between the 3-D unit cell and the 2-D plate. The Navier solution is developed for the 2-D micropolar ESL-FSDT plate model to study the bending, buckling, and free vibration of simply-supported web-core sandwich panels. In a line load bending problem, a 2-D classical ESL-FSDT plate model yields displacement errors of 34-175% for face sheet thicknesses of 2-10 mm compared to a 3-D FE solution, whereas the 2-D micropolar model gives only small errors of 2.7-3.4% as it can emulate the 3-D deformations better through non-classical antisymmetric shear behavior and local bending and twisting.

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“…The program then constructs an associated weak form of the relevant equilibrium equations together with its finite-element implementation. Applications of the finite element method specific to second-gradient or micromorphic elasticity [4,5,6,7,8,9] are discussed in [10,11,12,13,14,15,16].…”

Section: Introductionmentioning

confidence: 99%