Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

Energy Absorption Properties of Periodic and Stochastic 3D Lattice Materials

Energy Absorption Properties of Periodic and Stochastic 3D Lattice Materials Architected lattices can be designed to have tailorable functionalities by controlling their constitutive elements. However, little work has been devoted to comparing energy absorption properties in different periodic three‐dimensional geometries to each other and to comparable foam‐like random structures. This knowledge is essential for the entire design process. In this work, the authors conduct a systematic and comprehensive computational study of the quasi‐static and dynamic energy absorption properties of various different geometries. They test compression loading over strain rates varying from 1 to 104 s−1. The authors analyze geometries with varying degrees of nodal connectivity, ranging from bending dominated to stretching dominated, at different orientations, and compare their response to equivalent stochastic lattices. Results show relatively high stress peaks in the periodic lattices, even in bending dominated lattices at certain orientations. Conversely, the stochastic geometries show a relatively constant stress response over large strains, which is ideal for energy absorbing applications. Still, results show that specific orientations of bending dominated periodic lattice geometries outperform their stochastic equivalents. This work can help to quickly identify the potential of different unit cell types and aid in the development of lattices for impulse mitigation applications, such as in protective sports equipment, automotive crashworthiness, and packaging. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Advanced Theory and Simulations Wiley

Energy Absorption Properties of Periodic and Stochastic 3D Lattice Materials

Download PDF
11 pages

Loading next page...
 
/lp/wiley/energy-absorption-properties-of-periodic-and-stochastic-3d-lattice-tSbuUZ8vv7
Publisher
Wiley
Copyright
© 2019 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim
eISSN
2513-0390
DOI
10.1002/adts.201900081
Publisher site
See Article on Publisher Site

Abstract

Architected lattices can be designed to have tailorable functionalities by controlling their constitutive elements. However, little work has been devoted to comparing energy absorption properties in different periodic three‐dimensional geometries to each other and to comparable foam‐like random structures. This knowledge is essential for the entire design process. In this work, the authors conduct a systematic and comprehensive computational study of the quasi‐static and dynamic energy absorption properties of various different geometries. They test compression loading over strain rates varying from 1 to 104 s−1. The authors analyze geometries with varying degrees of nodal connectivity, ranging from bending dominated to stretching dominated, at different orientations, and compare their response to equivalent stochastic lattices. Results show relatively high stress peaks in the periodic lattices, even in bending dominated lattices at certain orientations. Conversely, the stochastic geometries show a relatively constant stress response over large strains, which is ideal for energy absorbing applications. Still, results show that specific orientations of bending dominated periodic lattice geometries outperform their stochastic equivalents. This work can help to quickly identify the potential of different unit cell types and aid in the development of lattices for impulse mitigation applications, such as in protective sports equipment, automotive crashworthiness, and packaging.

Journal

Advanced Theory and SimulationsWiley

Published: Oct 1, 2019

Keywords: ; ; ; ;

References

  • Spatial tessellations: Concepts and Applications of Voronoi Diagrams
    Okabe, A.; Boots, B.; Sugihara, K.; Chiu, S. N.
  • Computing in Euclidean Geometry
    Fortune, S.
  • Dynamic Response and Failure of Cellular Networks
    Vural, M.
  • Cellular Solids: Structure and Properties
    Gibson, L. J.; Ashby, M. F.
  • Behavior of aluminum at elevated strain rates and temperatures
    Semb, E.
  • Metal Foams: a Design Guide
    Ashby, M. F.; Evans, T.; Fleck, N. A.; Hutchinson, J.; Wadley, H.; Gibson, L.