Publication detail
Numerical analysis of geometrically induced hardening in planar architectured materials
F. Siska, J. Cizek, H. Seiner, I. Dlouhy
English title
Numerical analysis of geometrically induced hardening in planar architectured materials
Type
journal article in Web of Science
Language
en
Original abstract
The presented study focuses on the evaluation of mechanical performance of architectured materials with planar geometry. The main objective is to investigate the effect of geometrically induced hardening of different geometrical patterns during uniaxial loading. The analysis is performed by FEM on a basic cell that represents a particular geometry. Seven different geometries, each with three volume fractions of the reinforcement (0.1, 0.4 and 0.8) are analyzed for four combinations of perfect plastic materials. The matrix material is kept identical, while 4 variants of the reinforcement material are taken into account. The results show that geometry can induce hardening that expands the region of a stable material deformation beyond the capabilities of its constituent materials. An improvement in the strain energy density due to the hardening can be achieved either by a higher strength attained by using the reinforcement aligned to the loading direction, or by a higher strain attained by using the reinforcement arranged like cantilever beam that is inclined or perpendicular to the loading. The best performance regarding strain energy density among the different volume fractions and materials combinations is achieved for the geometry with a combination of both types of reinforcement.
English abstract
The presented study focuses on the evaluation of mechanical performance of architectured materials with planar geometry. The main objective is to investigate the effect of geometrically induced hardening of different geometrical patterns during uniaxial loading. The analysis is performed by FEM on a basic cell that represents a particular geometry. Seven different geometries, each with three volume fractions of the reinforcement (0.1, 0.4 and 0.8) are analyzed for four combinations of perfect plastic materials. The matrix material is kept identical, while 4 variants of the reinforcement material are taken into account. The results show that geometry can induce hardening that expands the region of a stable material deformation beyond the capabilities of its constituent materials. An improvement in the strain energy density due to the hardening can be achieved either by a higher strength attained by using the reinforcement aligned to the loading direction, or by a higher strain attained by using the reinforcement arranged like cantilever beam that is inclined or perpendicular to the loading. The best performance regarding strain energy density among the different volume fractions and materials combinations is achieved for the geometry with a combination of both types of reinforcement.
Keywords in English
planar architecture materials
Released
03.11.2019
Publisher
ELSEVIER SCI LTD
Location
OXFORD
ISSN
1879-1085
Volume
233
Number
111633
Pages from–to
1–10
Pages count
10
BIBTEX
@article{BUT170590,
author="Filip {Šiška} and Filip {Šiška} and Jan {Čížek} and Hanuš {Seiner} and Ivo {Dlouhý},
title="Numerical analysis of geometrically induced hardening in planar architectured materials",
year="2019",
volume="233",
number="111633",
month="November",
pages="1--10",
publisher="ELSEVIER SCI LTD",
address="OXFORD",
issn="1879-1085"
}