A Novel Efficient Prediction Method for Microscopic Stresses of Periodic Beam-like Structures

Abstract: This paper presents a novel superposition method for effectively predicting the microscopic stresses of heterogeneous periodic beam-like structures. The efficiency is attributed to using the microscopic stresses of the unit cell problem under six generalized strain states to construct the structural microscopic stresses. The six generalized strain states include one unit tension strain, two unit bending strains, one unit torsion strain, and two linear curvature strains of a Timoshenko beam. The six microscopic… Show more

“…1. The macroscopic structure is a 1D Navier-Euler-Bernoulli-Saint-Venant beam problem [13] that can be decomposed into a series of microscopic 3D structure. The length l of the representative microscopic 3D model is determined by:…”

Computational homogenization method for the bending analysis of submarine power cables

“…1. The macroscopic structure is a 1D Navier-Euler-Bernoulli-Saint-Venant beam problem [13] that can be decomposed into a series of microscopic 3D structure. The length l of the representative microscopic 3D model is determined by:…”

Computational homogenization method for the bending analysis of submarine power cables

“…Several attempts have been made to perform homogenization of beam-like structures [25][26][27][28][29]23,[30][31][32]. In [31,32], the authors have proposed a two-dimensional homogenization scheme by reducing the original 3D microscopic problem to a 2D finite element simulation on the cross-section.…”

A mixed stress-strain driven computational homogenization of spiral strands

A rheological constitutive model to predict the anisotropic biaxial bending behavior of spiral strands subjected to variable axial force