Multiscale thermal and thermo-structural optimization of three-dimensional lattice structures

This paper develops a robust framework for the multiscale design of three-dimensional lattices with macroscopically tailored thermal and thermo-structural characteristics. A multiscale approach is implemented where the discrete evaluations of small-scale lattice unit cell characteristics are convert...

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Bibliographic Details
Published in:Structural and multidisciplinary optimization 2022, Vol.65 (1), Article 13
Main Authors: Imediegwu, Chikwesiri, Murphy, Ryan, Hewson, Robert, Santer, Matthew
Format: Article
Language:English
Subjects:
Computational Mathematics and Numerical Analysis
Continuity (mathematics)
Design optimization
Engineering
Engineering Design
Lattices (mathematics)
Material properties
Multiscale analysis
Optimization
Research Paper
Response surface methodology
Structural response
Theoretical and Applied Mechanics
Unit cell
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Summary:This paper develops a robust framework for the multiscale design of three-dimensional lattices with macroscopically tailored thermal and thermo-structural characteristics. A multiscale approach is implemented where the discrete evaluations of small-scale lattice unit cell characteristics are converted to response surface models so that the properties exist as continuous functions of the lattice micro-parameters. The derived framework constitutes free material optimization in the space of manufacturable lattice micro-architecture. The optimization of individual lattice member dimensions is enabled by the adjoint method and the explicit expressions of the response surface material property sensitivities. The approach is demonstrated by solving thermal and thermo-structural optimization problems, significantly extending previous work which focused on linear structural response. The thermal optimization solution shows a design with improved optimality compared to the SIMP methodology. The thermo-structural optimization solution demonstrates the method’s capability for attaining a prescribed displacement in response to temperature gradients.
ISSN:1615-147X
1615-1488
DOI:10.1007/s00158-021-03087-8