Abstract
Cuttlebone is a natural material possessing the multifunctional properties of high porosity, high flexural stiffness and compressive strength, making it a fine example of design optimization of cellular structures created by nature. Examination of cuttlebone using scanning electron microscopy (SEM) reveals an approximately periodic microstructure, appropriate for computational characterization using direct homogenization techniques. In this paper, volume fractions and stiffness tensors were determined based on two different unit cell models that were extracted from two different cuttlefish samples. These characterized results were then used as the target values in an inverse homogenization procedure aiming to re-generate microstructures with the same properties as cuttlebone. Unit cells with similar topologies to the original cuttlebone unit cells were achieved, attaining the same volume fraction (i.e. bulk density) and the same (or very close) stiffness tensor. In addition, a range of alternate unit cell topologies were achieved also attaining the target properties, revealing the non-unique nature of this inverse homogenization problem.
Original language | English |
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Pages (from-to) | 27-35 |
Number of pages | 9 |
Journal | Acta Mechanica Sinica |
Volume | 26 |
Issue number | 1 |
DOIs | |
Publication status | Published - Mar 2010 |
Keywords
- Inverse homogenization
- Cuttlebone microstructure
- Topology optimization
- Scanning electronic microscopy (SEM)
- Extra-light biomaterials
- ARAGONITIC CUTTLEFISH BONES
- TOPOLOGY OPTIMIZATION
- HYDROXYAPATITE SCAFFOLDS
- MULTIPHASE COMPOSITES
- THERMAL-CONDUCTIVITY
- COMPUTATIONAL DESIGN
- HOMOGENIZATION
- MICROSTRUCTURE
- CONSTRAINT
- PERIMETER