Active materials by four-dimension printing
Abstract
We advance a paradigm of printed active composite materials realized by directly printing glassy shape memory polymer fibers in an elastomeric matrix. We imbue the active composites with intelligence via a programmed lamina and laminate architecture and a subsequent thermomechanical training process. The initial configuration is created by three-dimension (3D) printing, and then the programmed action of the shape memory fibers creates time dependence of the configuration—the four-dimension (4D) aspect. We design and print laminates in thin plate form that can be thermomechanically programmed to assume complex three-dimensional configurations including bent, coiled, and twisted strips, folded shapes, and complex contoured shapes with nonuniform, spatially varying curvature. The original flat plate shape can be recovered by heating the material again. We also show how the printed active composites can be directly integrated with other printed functionalities to create devices; here we demonstrate this by creating a structure that can assemble itself.
- Publication:
-
Applied Physics Letters
- Pub Date:
- September 2013
- DOI:
- 10.1063/1.4819837
- Bibcode:
- 2013ApPhL.103m1901G
- Keywords:
-
- elastomers;
- filled polymers;
- laminates;
- plates (structures);
- polymer fibres;
- polymer structure;
- shape memory effects;
- thermomechanical treatment;
- three-dimensional printing;
- 81.05.Qk;
- 81.40.Gh;
- 81.40.Lm;
- 62.20.fg;
- 61.41.+e;
- Reinforced polymers and polymer-based composites;
- Other heat and thermomechanical treatments;
- Deformation plasticity and creep;
- Shape-memory effect;
- yield stress;
- superelasticity;
- Polymers elastomers and plastics