Affordable Access

Access to the full text

Shell-to-Beam Numerical Homogenization of 3D Thin-Walled Perforated Beams

Authors
  • staszak;, natalia
Publication Date
Feb 28, 2022
Identifiers
DOI: 10.3390/ma15051827
OAI: oai:mdpi.com:/1996-1944/15/5/1827/
Source
MDPI
Keywords
Language
English
License
Green
External links

Abstract

Determining the geometric characteristics of even complex cross-sections of steel beams is not a major challenge nowadays. The problem arises when openings of various shapes and sizes appear at more or less regular intervals along the length of the beam. Such alternations cause the beam to have different stiffnesses along its length. It has different bending and shear stiffnesses at the opening point and in the full section. In this paper, we present a very convenient and easy-to-implement method of determining the equivalent stiffness of a beam with any cross-section (open or closed) and with any system of holes along its length. The presented method uses the principles of the finite element method (FEM), but does not require any formal analysis, i.e., solving the system of equations. All that is needed is a global stiffness matrix of the representative volumetric element (RVE) of the 3D representation of a beam modeled with shell finite elements. The proposed shell-to-beam homogenization procedure is based on the strain energy equivalence, and allows for precise and quick determination of all equivalent stiffnesses of a beam (flexural and shear). The results of the numerical homogenization procedure were compared with the existing analytical solution and experimental results of various sections. It has been shown that the results obtained are comparable with the reference results.

Report this publication

Statistics

Seen <100 times