Known as a versatile material that can be used in a wide range of applications, elastomers also offer both electrical and thermal insulation. Because of this they are currently popular for use in both electronics and smart biomedical devices, which require material that is flexible and adaptable. Manufacturing has been stumping modern researchers, however, due to the thermal curing process which requires those manufacturing it to cut, mold, and cast.
“We have developed the most stretchable 3D printable elastomer in the world. Our new elastomers can be stretched by up to 1100% which is more than five times the elongation at break of any commercially available elastomer that is suitable for UV curing based 3D printing techniques,” said Assistant Professor Qi (Kevin) Ge from the SUTD’s DManD Centre, who is one of the co-leaders in developing the SUV elastomers. “The new SUV elastomers enable us to directly print complicated geometric structures and devices such as a 3D soft robotic gripper within an hour. Compared to traditional molding and casting methods, using UV curing based 3D printing with the SUV elastomers significantly reduces the fabrication time from many hours, even days, to a few minutes or hours as the complicated and time-consuming fabrication steps such as mold-building, molding/demolding, and part assembly are replaced by a single 3D printing step.”
HUJI has provided us this video to show the stretch possible in this material:
These research findings were recently published in the Journal of Advanced Materials, in ‘Highly Stretchable and UV Curable Elastomers for Digital Light Processing Based 3D Printing,’ by Dinesh K. Patel, Amir Hosein Sakhaei, Michael Layani, Biao Zhang, Qi Ge, and Shlomo Magdassi. The researchers explain that in their work so far they have been able to create ‘highly deformable complex 3D hollow structures’ like:
- Balloons
- Soft actuators
- Grippers
- Bucky ball electronical switches
“Overall, we believe the SUV elastomers, together with the UV curing based 3D printing techniques, will significantly enhance the capability of fabricating soft and deformable 3D structures and devices including soft actuators and robots, flexible electronics, acoustic metamaterials, and many other applications,” said Professor Shlomo Magdassi, a co-leader of the project at HUJI and CREATE.
Discuss in the 3D Printed Elastomers forum at 3DPB.com.