Carbon M1 3D printer
It’s been well over a year since Carbon had the entire 3D printing industry clamoring in excitement about their exhilaratingly fast and potentially revolutionary Continuous Liquid Interface Production (CLIP) technology, which was unveiled by CEO Joseph DeSimone during a TED Talk back in March 2015. Earlier this year, we finally received the first impressions of Carbon’s M1 commercial digital light projector (DLP), the first-ever 3D printer equipped with CLIP technology. The technology is unique in its use of light and oxygen to cure a photosensitive resin, creating a ‘dead zone’ that offers a thin layer of uncured resin between the window and the object. This process has effectively eliminated layering, leading to unbelievable speed capabilities, which has gotten the entire 3D printing community standing at attention and ready for more.
Since the unveiling of the M1, Carbon has partnered with a handful of companies both inside and outside of the 3D printing industry, inking deals with major companies such as Kodak and Ford, as well as 3D printing service providers like the France-based Sculpteo. It seems pretty evident that Sculpteo is truly enjoying their experimentation with the M1, having released a breakdown of the four CLIP-compatible resins in their blog last month. Now, Sculpteo is individually focusing on each one of Carbon’s resin materials in a new series featuring the expertise of 3D printing engineer Chris Lau, to whom Sculpteo has awarded the title of ‘M1 specialist’. In their first post, Lau and Sculpteo discuss the details of their favorite resin in the entire bunch, the Rigid Polyurethane (RPU).
Nozzle part printed in RPU resin
The RPU is a black opaque resin that gives the impression of a slightly smooth and shiny injection molded part after curing process is complete. If the resin is polished after being cured, it takes on a strong matte appearance. Although the CLIP technology prides itself on eliminating layers from the 3D printing process, a finished object in the RPU might look layered depending on the orientation of the 3D model, but according to Sculpteo, these are just artifacts coming about from the CLIP process, rather than machine layering that would suggest a more fragile part. In fact, stiffness and strength are what the Rigid Polyurethane are prized for, outperforming ABS plastic while holding its own against nylon.
Bike pedals printed in RPU resin
RPU is ideal for printing mechanical parts that require toughness, as well as resistance to heat and abrasion. This particular resin is ideal for functional and use-end parts where laser sintered Nylon just doesn’t cut it. Thus far, Sculpteo has utilized for production by a number of their pilot customers, many of whom have turned to the RPU for its exceptional strength and ductility. The resolution promoted by the RPU resin is extremely high, capable of 3D printing features as thin as 0.25 mm. The suggested thickness of resin is heavily dependent on the structural features of the 3D model, which can range from relatively flexible to tough and rigid.
As for printing moving components, Sculpteo still has a bit more experimentation to perform with support structures, which has prevented them from offering interlocking designs with any CLIP resin thus far, although it should be possible in theory. Another issue that could arise when printing with RPU is the inability to print a design with an enclosed hollow region, which will lead to resin being trapped within the object’s cavity. Because of this, 3D models prepped for printing on the M1 should be equipped with an opening to help drain the excess resin out.
