Optimized growth and reorientation of anisotropic material based on evolution equations

verfasst von: D.R. Jantos, P. Junker, K. Hackl
Abstract: Modern high-performance materials have inherent anisotropic elastic properties. The local material orientation can thus be considered to be an additional design variable for the topology optimization of structures containing such materials. In our previous work, we introduced a variational growth approach to topology optimization for isotropic, linear-elastic materials. We solved the optimization problem purely by application of Hamilton’s principle. In this way, we were able to determine an evolution equation for the spatial distribution of density mass, which can be evaluated in an iterative process within a solitary finite element environment. We now add the local material orientation described by a set of three Euler angles as additional design variables into the three-dimensional model. This leads to three additional evolution equations that can be separately evaluated for each (material) point. Thus, no additional field unknown within the finite element approach is needed, and the evolution of the spatial distribution of density mass and the evolution of the Euler angles can be evaluated simultaneously.
Organisationseinheit(en): Institut für Kontinuumsmechanik
Typ: Artikel
Journal: Computational mechanics
Band: 62
Seiten: 47-66
Anzahl der Seiten: 20
ISSN: 0178-7675
Publikationsdatum: 2018
Publikationsstatus: Veröffentlicht
Peer-reviewed: Ja
ASJC Scopus Sachgebiete: Numerische Mechanik, Meerestechnik, Maschinenbau, Theoretische Informatik und Mathematik, Computational Mathematics, Angewandte Mathematik
Elektronische Version(en): https://doi.org/10.1007/s00466-017-1483-3 (Zugang: Geschlossen)
: Details im Forschungsportal „Research@Leibniz University“

BibTeX

@article{c24223a69e5a454abae232474e51eb1f,
title = "Optimized growth and reorientation of anisotropic material based on evolution equations",
abstract = "Modern high-performance materials have inherent anisotropic elastic properties. The local material orientation can thus be considered to be an additional design variable for the topology optimization of structures containing such materials. In our previous work, we introduced a variational growth approach to topology optimization for isotropic, linear-elastic materials. We solved the optimization problem purely by application of Hamilton{\textquoteright}s principle. In this way, we were able to determine an evolution equation for the spatial distribution of density mass, which can be evaluated in an iterative process within a solitary finite element environment. We now add the local material orientation described by a set of three Euler angles as additional design variables into the three-dimensional model. This leads to three additional evolution equations that can be separately evaluated for each (material) point. Thus, no additional field unknown within the finite element approach is needed, and the evolution of the spatial distribution of density mass and the evolution of the Euler angles can be evaluated simultaneously.",
keywords = "Anisotropic, Energy methods, Internal variable, Optimization",
author = "D.R. Jantos and P. Junker and K. Hackl",
note = "Publisher Copyright: {\textcopyright} 2017, Springer-Verlag GmbH Germany.",
year = "2018",
doi = "10.1007/s00466-017-1483-3",
language = "English",
volume = "62",
pages = "47--66",
journal = "Computational mechanics",
issn = "0178-7675",
publisher = "Springer Verlag",
number = "1",
}