Print Email Facebook Twitter 2D Lattice Materials for Actuation Title 2D Lattice Materials for Actuation Author Nelissen, Wiebe (TU Delft Mechanical, Maritime and Materials Engineering) Contributor Ayas, C. (mentor) van Keulen, A. (graduation committee) Zadpoor, A.A. (graduation committee) Degree granting institution Delft University of Technology Date 2018-02-19 Abstract Externally triggered lengthening or shortening (actuation) of one or more members in a lattice material can be used to achieve macroscopic shape changes. The three main attributes looked for in 2D lattice materials to be deemed suitable for actuation are in-plane isotropy, high specific elastic properties and limited energy requirement for actuation. However, no infallible topological criteria have yet been discovered that determine which micro-architectures meet these requirements. The Kagome micro-architecture yields the best-performing lattice material for actuation known to date. This thesis contributes to the search for micro-architectures that perform similar to Kagome lattice material, or even outperform it. Four novel micro-architectures are introduced. Each of the new micro-architectures is verified to constitute a stiff (i.e. stretching-dominated) isotropic lattice material. Still, not all of them result in optimal elastic moduli. One of the proposed designs does perform identically to the Kagome structure in terms of elastic moduli. Moreover, it requires less energy for actuation in the range of relative densities of interest. On the other hand, its attenuation distance is shorter; actuation deformations damp out within a shorter distance than in Kagome lattice material. Subject 2D lattice materialsself-stressmechanical metamaterialsmicro-architectureinfinite structuresisotropystatic and kinematic determinacyhomogenisationactuationshape morphinglightweightfoamsmechanisms To reference this document use: http://resolver.tudelft.nl/uuid:f2846097-ae51-4304-87d3-832afb88ac44 Part of collection Student theses Document type master thesis Rights © 2018 Wiebe Nelissen Files PDF thesis.pdf 12.36 MB Close viewer /islandora/object/uuid:f2846097-ae51-4304-87d3-832afb88ac44/datastream/OBJ/view