Additive manufacturing using silicone paste in water could have biomedical, soft robotics applications.
Using the principles behind the formation of sandcastles from wet sand, researchers have achieved 3D printing of flexible and porous silicone rubber structures. They accomplished this through a new technique that combines water with solid and liquid forms of silicone into a pasty ink that can be fed through a 3-D printer.
The finding could have biomedical applications and uses in soft robotics.
In a paper published in Advanced Materials, corresponding author Orlin Velev and colleagues show that, in a water medium, liquid silicone rubber can be used to form bridges between tiny silicone rubber beads to link them together—much as a small amount of water can shape sand particles into sandcastles.
Interestingly, the technique can be used in a dry or a wet environment, suggesting that it has the potential to be used in live tissue—think of an ultraflexible mesh encapsulating a healing droplet, or a soft bandage that can be applied or even directly printed on some portion of the human body, for example.
“There is great interest in 3-D printing of silicone rubber, or PDMS, which has a number of useful properties,” said Velev, professor of chemical and biomolecular engineering at North Carolina State University. “The challenge is that you generally need to rapidly heat the material or use special chemistry to cure it, which can be technically complex.
“Our method uses an extremely simple extrudable material that can be placed in a 3D printer to directly prototype porous, flexible structures – even under water,” Velev added. “And it is all accomplished with a multiphasic system of just two materials – no special chemistry or expensive machinery is necessary. The ‘trick’ is that both the beads and the liquid that binds them are silicone, and thus make a very cohesive, stretchable and bendable material after shaping and curing.”
For more 3D printing news, check out these 6 Next Gen 3D Printing Technologies That Might Change Everything.