We love forward thinking companies that take a risk and do something different. iRobot, the company behind the iconic Roomba, just released the newest version of their Roomba Create — a programmable Roomba (minus the vacuum) that can be hacked and programmed to do all sorts of things.
The company developed the Create with STEM students in mind — a robotics learning platform. It came out originally back in 2007, and we’ve covered many hacks that have made use of it. Many. Like, a lot. One of our favorites has got to be this data center monitoring robot that makes use of the platform!
Anyway, the newest version of the Create features the typical hardware upgrades you’d expect, and with some special emphasis on 3D printing. In fact, the CEO of iRobot [Colin Angle] thinks that 3D printing is going to make a big difference in a few years:
“Your Roomba could be a software file that you print at home,” he says. He says the Create’s new features are a way for the company to get ready for that day, while also providing a platform that educators and hobbyists can use to tinker.
Kudos to you guys, iRobot! We just wish people would stop giving Roomba’s knives…
The shocking thing is not that this happened. The shocking thing is how normal it seems. An astronaut inside a space station needed a ratcheting socket wrench. Someone else on Earth drew it up on a computer then e-mailed the astronaut. The astronaut clicked a button and then the tool was squirted out of a nozzle. Then he picked up and used the tool for the job he needed done. No big deal.
The story itself is almost uneventful – of course we can do these things now. Sure, it happens to be the first time in mankind’s history we have done this. Yes, it is revolutionary to be able to create tools on demand rather than wait months for one to be built planet-side and put onto the next resupply rocket. But, amateurs living in places without even widespread electricity or running water have already built these machines from actual garbage.
Every once in a while a story slaps us with how much the future is now.
These particular 3d prints were duplicated on the ground, and both sets preserved for future comparative analysis to see if microgravity has any effect on 3d prints. They have an eye on sending them to Mars, a journey where resupply is more than just a couple-month inconvenience.
See the first link above for more detail and photos of NASA’s 3d printer and the Microgravity Science Glovebox in the Columbus laboratory module.
There’s just something about the holidays and man’s best friend that brings out the best in people. [Tara Anderson], Director of CJP Product Management at 3D Systems, fostered a husky mix named Derby. Derby was born with a congenital defect: his forelegs were underdeveloped with no paws. This precluded the poor fellow from running around and doing all of the things dogs love to do. [Tara] had fitted him with a wheel cart, but she still felt that Derby deserved more mobility and freedom. Deciding that 3D-printed prosthetics was the answer, she turned to her colleagues and collaborated with Derrick Campana, a certified Animal Orthotist, to create a new set of forelegs for Derby.
The design is different from typical leg prosthetics; Tara felt that the typical “running man” design would not work for a dog, since they’d just sink right into the ground. Instead, the “loop” design was used, allowing for more playful canine antics. They were constructed using MultiJet Printing on the 3DS’ ProJet 5500X. MultiJet Printing enabled the prosthetics to be printed with firm and soft parts, both needed for comfort and durability.
Continue reading “Derby’s Got Legs, He Knows How to Use Them”
Now this is some seriously cool stuff. The folks over at FormLabs decided to try a little experiment to test the optical clarity of their clear resin. It’s pretty damn clear.
Using their own slicing software, PreForm, [Craig Broady] printed the lens piece in an orientation that would maximize resin flow around the lens to help prevent defects, keeping it as smooth as possible. While the printed part looks quite clear, all lenses require some form of polishing to become optically clear. It was printed with a 50 micron resolution, and [Craig] used a power drill to sand the lens down from 220 grit to 2000 grit sand paper.
Continue reading “3D Printed Lenses Open Up Possibilities”
[Paul Williams] wrote in to tell us about his most recent and dangerous endeavor. Marriage.
As a masters student in Mechanical Engineering, he wanted to give his wife (to be) to be a completely unique engagement ring — but as you can imagine, custom engagement rings aren’t cheap. So he decided to learn how to make it himself.
During the learning process he kept good notes and has produced a most excellent Instructable explaining the entire process — How to make the tools you’ll need, using different techniques and common problems you might have. He even describes in detail how to make your own mini-kiln (complete with PID control), a vacuum chamber, a wax injector and even the process of centrifugal casting. Continue reading “Casting Engagement Rings (Or Other Small Metal Parts!)”
There are 3D printing filaments out there with a lot of interesting properties. Whether it’s the sanded-down MDF feel you get from Laywood, the stretchy and squishy but somehow indestructible feel of Ninjaflex, or just regular ‘ol PLA, there’s a filament out there for just about any use. Even optically clear printed objects. Yes, you can now do some post-processing on printed parts to make T-glase crystal clear.
The big advance allowing translucent parts to be made clear is a new product from Smooth-On that’s meant to be a protective and smoothing coating for 3D printed objects. With PLA, ABS, and powder printed parts, this coating turns objects shiny and smooth. Strangely – and I don’t think anyone planned this – it also has the same index of refraction as T-glase. This means coating an object printed with T-glase will render the layers invisible, smooth out the tiny bumps in the print, and turn a single-walled object clear.
There is a special technique to making clear objects with T-glase. The walls of the print must be a single layer. You’ll also want a perfect layer height on your print – you’re looking for cylindrical layers, not a nozzle that squirts out to the side.
The coating for the pictures above was applied on a makeshift lathe built out of an electric drill and a sanding pad. This gave the coating a nice, even layer until it dried. After a few tests, it was determined lenses could be printed with this technique. It might not be good enough for 3D printed eyeglasses, but it’s more than sufficient for creating windows for a model, portholes for an underwater ROV, or anything else where you want nothing but light inside an enclosure.
Ever heard of the summer camp called Superhero Cyborgs? It’s where [Coby Unger] met nine-year-old [Aidan Robinson] and helped him design his very own custom prosthetic arm.
The camp is put on by KIDmob for kids who have various limb disabilities, and helps give them the tools and guidance to be able to make their very own prosthetics. Some of the designs the children come up with are cool, useful, pretty and sometimes not overly functional — but [Aidan’s] designs really intrigued [Coby] who is a designer and part of the staff at Pier 9, a world-class fabrication facility (and makerspace) run by Autodesk.
There’s a lot of problems with prosthetics for children. They’re very expensive, kids don’t stay the same size, and even though they might cost a lot, they don’t necessarily work that well. [Aidan] had a few commercial options but didn’t like any of them, so much so that he preferred not wear them period. But when he attended the camp he realized he had the ability to design a prosthetic that he’d actually want to wear.
Continue reading “Kid Designs His Own Prosthetic Arm at a Summer Camp”