Self-expanding/shrinking structures by 4D printing

• Published in: Smart materials and structures Vol. 25; no. 10; pp. 105034 - 105048
• Main Authors: Bodaghi, M, Damanpack, A R, Liao, W H
• Format: Journal Article
• Language: English
• Published: IOP Publishing 01.10.2016
• Subjects: 4D printing; constitutive modeling; experimental validation; finite element method; self-expanding/shrinking; shape memory polymers
• ISSN: 0964-1726; 1361-665X
• DOI: 10.1088/0964-1726/25/10/105034

The aim of this paper is to create adaptive structures capable of self-expanding and self-shrinking by means of four-dimensional printing technology. An actuator unit is designed and fabricated directly by printing fibers of shape memory polymers (SMPs) in flexible beams with different arrangements. Experiments are conducted to determine thermo-mechanical material properties of the fabricated part revealing that the printing process introduced a strong anisotropy into the printed parts. The feasibility of the actuator unit with self-expanding and self-shrinking features is demonstrated experimentally. A phenomenological constitutive model together with analytical closed-form solutions are developed to replicate thermo-mechanical behaviors of SMPs. Governing equations of equilibrium are developed for printed structures based on the non-linear Green-Lagrange strain tensor and solved implementing a finite element method along with an iterative incremental Newton-Raphson scheme. The material-structural model is then applied to digitally design and print SMP adaptive lattices in planar and tubular shapes comprising a periodic arrangement of SMP actuator units that expand and then recover their original shape automatically. Numerical and experimental results reveal that the proposed planar lattice as meta-materials can be employed for plane actuators with self-expanding/shrinking features or as structural switches providing two different dynamic characteristics. It is also shown that the proposed tubular lattice with a self-expanding/shrinking mechanism can serve as tubular stents and grippers for bio-medical or piping applications.