Smart International, an authorized global brand licensee of 3D printing for Kodak, announced that KODAK 3D Printing will be expanding its range of materials to include Acrylic and Nylon 6/66/12, as well as launching a new accessory line to enable users of the KODAK Portrait 3D printer to expand on the materials they can print with.
Acrylic, a new filament designed by KODAK 3D Printing, combines polycarbonate properties which deliver on high rigidity and are light conductive, while also being easy to print. It is well-suited to optical applications as the material conducts light, allowing for the 3D printing of interesting prototypes or for pieces requiring high transparency. In addition,, the new Acrylic is low-friction and can withstand high temperatures. Due to its low friction coefficient, it works well with moveable parts.
Nylon 6/66/12 has also been introduced, as strong as traditional Nylon, but with greater flexibility. Unlike traditional Nylons, it is low warping and allows for better printing of fine details and overhangs. Used in conjunction with the KODAK Portrait 3D Printer, which has been designed specifically to print high-temperature engineering materials, with a fully enclosed chamber and robust all-steel structure, it allows for less warp and more successful prints. Nylon 6/66/12 is particularly suitable for parts that need to be very strong with tensile resistance, or strong parts with fine details.
In addition to these two materials, KODAK 3D Printing is also launching a range of accessories to complement the KODAK Portrait and to give even more options with its dual extrusion system. First to be available are two mirrored E3D hotends, one all-metal and one PTFE, which will enable users to replace one of the existing hotends so they can use 2 all-metals or 2 PTFE on the same machine. This will open up the possibilities for dual material prints using two high-temperature or two low-temperature materials, and also for two color combinations.
Filed Under: 3D printing • additive manufacturing • stereolithography