Home / Timeline / 2017
Album Published

5-diamond ring with matching bands

This custom engagement ring and wedding band set was cast in palladium from 3D-printed wax. The engagement ring was designed to incorporate 5 diamonds that the client already owned in an asymmetrical pattern. The couple's wedding bands each have the same twisting pattern of cells but they spin in opposite directions. The wife's wedding band nestles perfectly against one edge of the engagement ring.

Album Published

dress in motion (1 new item)

The Kinematics Dress is a technical achievement but its also an article of clothing. We designed it with comfort and durability in mind, aiming to make a 3D-printed garment that you can actually wear, one that invites movement instead of constraining it.

Album Published

Kinematics Dress 11 (9 new items)

The eleventh version of our Kinematics Dress was 3D-printed in December 2016. It is composed of 1,839 interlocking panels that were 3D-printed as a single computationally folded piece. This dress features a unique stripe pattern of solid and perforated panels. It was exhibited at the National Centre for Craft & Design in Sleaford, UK in the exhibition "3D-printing: the good, the bad, and the beatiful" in 2017. It was also shown in the "3D Fashion" runway show presented by LEXUS in cooperation with VOXELWORLD on 7/22/2017 at PlatformFashion Düsseldorf. 3D-printed in nylon by Selective Laser Sintering by Shapeways 1,839 interloacking pieces print date: 12/2016 dress size: US 0

Album Published

Cellular Wedding Bands

We created these custom palladium wedding bands with a client using our Cell Cycle app. The two bands have a similar structure but twist in opposite directions.

Album Published

Kinematics Link

A few years ago, we started thinking about applying the design+simulation techniques of our Kinematics system to other types of textile structures like chainmail. The Kinematics Dress is made up of hinged triangles which tessellate to cover the body. The hinges not only create a garment with fabric-like motion but also enable us to fold the garment computationally to produce a smaller configuration for efficient 3D-printing. Hinges have a very limited range of motion though, only allowing for rotation around a fixed axis. A loose, unconstrained structure like chainmail should be able to compress much more compactly. Recently, Formlabs contacted us about using some of our designs for their new secret project, an affordable SLS 3D-printer, the Fuse 1. They were particularly interested in printing one of our garments, but their machine is MUCH smaller than the 3D printer that fabricated our other garments. Our dresses are printed on the largest EOS printer at Shapeways, which has a build volume of 65x55x35 cm. The Formlabs Fuse 1 is only 1/14th the size of that machine. A Kinematics Dress definitely wouldn’t fit in there! Rather than dismiss the idea of being able to print clothing in such a small build volume, we built a new chainmail system to achieve much greater compression. We fit a Kinematics Link bodice (US size 6) in about half the build space of the Fuse 1. The bounding box of this prototype was 13x13x16.8cm, approximately 4% of the bounding box of the unfolded design. That’s a lot of compression! The Kinematics Link Bodice is composed of 11,311 interlocking parts, making it the most intricate garment we’ve ever created (the most intricate kinematics dress we’ve made only had 3,212). With this level of detail, the resulting garment is considerably lighter, more flexible, and more fabric-like than our previous garments.