Now, a study by Marius Wagner, Tian Chen, and Kristina Shea of the Swiss Federal Institute of Technology Zurich (ETH Zurich) outlines how shape memory polymers can be the catalyst for producing adaptable materials that also go back to their original shape when heated. Their research explains how they used the following:
- 3D printing
- Thermoviscoelastic meta-materials
- Programmable design
“4D printing has large untapped potential in applications where configuration change cannot be manually achieved and where electromechanical actuation is not feasible, for example, in aerospace and in medical fields,” state the researchers in their paper. “In addition, 4D designs have the advantage of volume and support reduction.”
Such experimentation has been challenging in past projects by other researchers. The team examined these issues closely, and decided to implement material that could be ’tiled to form active structures.’ They were able to create more accurate design through their programming—and focused heavily on more simplified procedures.
“To simplify the fabrication process, the proposed meta-materials consist of a single material. They can be fabricated with inexpensive inkjet printing processes using commercially available materials. This also broadens the potential for fabricating 4D designs for a variety of applications,” states the team in their paper.
The scientists used a Stratasys Objet500 Connex3 3D printer for creating the necessary meta-materials, fabricated with VeroWhitePlus RGD835. They tested four different parameters:
- Glass transition temperature Tg
- The fully relaxed modulus
- The coefficient of thermal expansion (CTE)
- Frequency sweeps of the storage modulus at different temperatures
The three point bending experiment was then performed to test the shape memory, and compared to other simulations using the same material model. According to the researchers, temperature was used as input for the specimen temperature in the finite element simulation.
“For simulation of the meta-materials, we adapt a viscoelastic constitutive model with data from thermoviscoelastic material characterization experiments. The accuracy of the model is shown with a three-point bending test. To reduce computational effort, a reduced beam model is constructed to predict forces and deformations of complex active structures. To demonstrate that the meta-materials can conform to a given boundary, a letter based structure is fabricated and programmed into a circular shape. Simulation results confirm the behavior,” concluded the researchers.
Read more about this innovative research here.
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[Source / Images: Large Shape Transforming 4D Auxetic Structures]