Simple single-scale microstructures based on optimal rank-3 laminates

With the goal of identifying optimal elastic single-scale microstructures for multiple loading situations, the paper shows that qualified starting guesses, based on knowledge of optimal rank-3 laminates, significantly improves chances of convergence to near optimal designs. Rank-3 laminates, optimal...

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Veröffentlicht in:	Structural and multidisciplinary optimization 2019-04, Vol.59 (4), p.1021-1031
Hauptverfasser:	Träff, E., Sigmund, O., Groen, J. P.
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Sprache:	eng
Schlagworte:	Approximation Computational Mathematics and Numerical Analysis Engineering Engineering Design Homogenization Laminates Manufacturability Microstructure Research Paper Theoretical and Applied Mechanics
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container_title	Structural and multidisciplinary optimization
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creator	Träff, E. Sigmund, O. Groen, J. P.
description	With the goal of identifying optimal elastic single-scale microstructures for multiple loading situations, the paper shows that qualified starting guesses, based on knowledge of optimal rank-3 laminates, significantly improves chances of convergence to near optimal designs. Rank-3 laminates, optimal for a given set of anisotropic loading conditions, are approximated on a single scale using a simple mapping approach. We demonstrate that these mapped microstructures perform relatively close to theoretical energy bounds. Microstructures with a performance even closer to the bounds can be obtained by using the approximated rank-3 structures in a further step as starting guesses for inverse homogenization problems. Due to the nonconvex nature of inverse homogenization problems, the starting guesses based on rank-3 laminates outperform classical starting guesses with homogeneous or random material distributions. Furthermore, the obtained single-scale microstructures are relatively simple, which enhances manufacturability. Results, obtained for a wide range of loading cases, indicate that microstructures with performance within 5–8% of the theoretical optima can be guarantied, as long as feature sizes are not limited by minimium size constraints.
doi_str_mv	10.1007/s00158-018-2180-3
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subjects	Approximation Computational Mathematics and Numerical Analysis Engineering Engineering Design Homogenization Laminates Manufacturability Microstructure Research Paper Theoretical and Applied Mechanics
title	Simple single-scale microstructures based on optimal rank-3 laminates
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