Topology Optimization with Matlab: Geometrically Non-Linear Optimum Solid Structures at Random Force Strengths

This paper aims to investigate multiple large-strain topology-optimized structures, by interpreting their overlay as a probability density function. Such a strategy is suited to finding an optimum design of silicon electrodes subject to a random contact. Using this method, and prescribing a zero net...

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Published inSolids Vol. 4; no. 2; pp. 94 - 115
Main Authors Werner, Marek, Bieler, Sören, Weinberg, Kerstin
Format Journal Article
LanguageEnglish
Published Saarbrücken MDPI AG 01.06.2023
Subjects
Algorithms
Electrolytes
Finite element analysis
finite strain
geometric non-linearity
Methods
Optimization techniques
Schwarz P surface
topology optimization
Online AccessGet full text
ISSN2673-6497
2673-6497
DOI10.3390/solids4020007

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Abstract This paper aims to investigate multiple large-strain topology-optimized structures, by interpreting their overlay as a probability density function. Such a strategy is suited to finding an optimum design of silicon electrodes subject to a random contact. Using this method, and prescribing a zero net-force constraint on the global system, the optimum structure is identified with a Schwarz P minimum-surface structure. Then, the optimum structure is subject to chemo-mechanically coupled cycling, in terms of an irreversible thermodynamic process, which shows the interplay between the mechanical and chemical fields. The Matlab-based optimization code is attached.
AbstractList This paper aims to investigate multiple large-strain topology-optimized structures, by interpreting their overlay as a probability density function. Such a strategy is suited to finding an optimum design of silicon electrodes subject to a random contact. Using this method, and prescribing a zero net-force constraint on the global system, the optimum structure is identified with a Schwarz P minimum-surface structure. Then, the optimum structure is subject to chemo-mechanically coupled cycling, in terms of an irreversible thermodynamic process, which shows the interplay between the mechanical and chemical fields. The Matlab-based optimization code is attached.
Author Werner, Marek
Weinberg, Kerstin
Bieler, Sören
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SubjectTerms Algorithms
Electrolytes
Finite element analysis
finite strain
geometric non-linearity
Methods
Optimization techniques
Schwarz P surface
topology optimization
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Title Topology Optimization with Matlab: Geometrically Non-Linear Optimum Solid Structures at Random Force Strengths
URI https://www.proquest.com/docview/2829870797
https://doaj.org/article/1bf24f26118e45bd8bca4536a4a52973
Volume 4
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