Directional mechanical properties and wave propagation directionality of Kagome honeycomb structures
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Publication:1658031
DOI10.1016/j.euromechsol.2015.12.003zbMath1406.74359OpenAlexW2213366769MaRDI QIDQ1658031
Publication date: 14 August 2018
Published in: European Journal of Mechanics. A. Solids (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.euromechsol.2015.12.003
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Cites Work
- Unnamed Item
- In-plane elastic buckling of hierarchical honeycomb materials
- Material microstructure optimization for linear elastodynamic energy wave management
- Single member actuation in large repetitive truss structures
- A rigorous homogenization method for the determination of the overall ultimate strength of periodic discrete media and an application to general hexagonal lattices of beams
- Homogenization and equivalent in-plane properties of two-dimensional periodic lattices
- Mechanical properties of two novel planar lattice structures
- Comparison of microscopic and macroscopic instabilities in a class of two-dimensional periodic composites
- Kagomé plate structures for actuation
- Yield surfaces of various periodic metal honeycombs at intermediate relative density
- The effects of non-periodic microstructure on the elastic properties of two-dimensional cellular solids
- The structural performance of the periodic truss
- Long-wave buckling of elastic square honeycombs subject to in-plane biaxial compression
- A review of homogenization and topology optimization I—homogenization theory for media with periodic structure
- On the design of two-dimensional cellular metals for combined heat dissipation and structural load capacity
- Design of multiphysics actuators using topology optimization. I: One-material structures. II: Two-material structures.
