Domus- Visualization Tools 3D Printing, Assignment 3
1. 3D-Printed Spy Drones Could Be Built at Sea
A 3D-printed drone was recently launched from a British military warship and successfully flew to shore, a demonstration that could pave the way for futuristic spy drones that can be printed at sea.
Engineers at the University of Southampton, in the United Kingdom, built the unmanned aircraft using 3D printing, which has been used to create everything from pelvic implants to a prosthetic tortoise shell. The drone was launched off the front of the Royal Navy warship HMS Mersey. It flew approximately 1,640 feet (500 meters) in just a few minutes, and landed safely on a beach in Dorset, England, the researchers said.
The 3D-printed aircraft, dubbed SULSA, has a wingspan that measures 4 feet (1.2 m) long, and it can fly up to 60 miles per hour (97 km/h). Drones like these could one day be used for military surveillance because they can fly almost silently, the researchers said.
The real challenge, the engineers said, was to create a robust, fast-flyingdrone that can be assembled easily in less than 5 minutes without the need for bolts or screws. The SULSA aircraft is made up of four 3D-printed parts that click into place like a puzzle toy.
The drone's pieces are made from nylon by a process called selective laser sintering (SLS), which uses a laser to fuse nylon powder into solid structures. This is technology that the University of Southampton has “pioneered over the last five years,” said Andy Keane, a professor of computational engineering at the University of Southampton.
Keane, who led the project, said the use of 3D-printed unmanned aerial vehicles (UAVs), like SULSA, is increasing because they are relatively cheap and quick to make.
"Typically, the print run takes 24 hours,” Keane said in a statement. "It takes another 24 hours to cool, so from the time we send them the files to having the part in your hand, it takes 48 hours."
This type of convenience may be invaluable for the military, because it could enable warfighters to custom-design surveillance drones and print them on-site, in remote locations or even at sea. "These things could be printed anywhere," Keane said.
The defense industry has been using 3D printing technology for a while, including to produce guns. The finished product is also separate from the design, so pieces can be printed out wherever they are needed as long as a 3D printer is available, the researchers said. As such, warfighters wouldn't need to depend on factories back in their home countries, and the military could avoid lengthy shipping times for replacement parts, which could be intercepted by hostile forces.
In a statement, the Royal Navy said they were "delighted" to assist with the development of SULSA and that the test flight was a "small glimpse into the innovation and forward thinking" of the future of this aircraft technology.
First Sea Lord Admiral Sir George Zambellas said that remotely piloted aircrafts have "proven their worth" already by surveying huge sea areas. He added that simple, automated systems have the potential to replace more complicated and expensive machines.
"We are after more and greater capability in this field which delivers huge value for money," he said in a statement. "And because it's new technology, with young people behind it, we're having fun doing it."
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2. 3D-Print a Brain with Free Government Library
People can now download, share and edit files for use in 3D printers from a new government website. The site has files that can be used to create models of anything from a human brain to deadly viruses.
The website, launched by the National Institutes of Health, is called theNIH 3D Print Exchange, and contains a library of files that a 3D printer can read and print. The files all relate to health and science; the available files include models of a human femur bone, the West Nile virus and a white matter section of the brain.
Users can also share their own files, edit exiting ones or create files using a tool that converts scientific data into ready-to-print 3D files.
"We created this website as kind of a way to have a YouTube-like experience, but instead of exchanging and sharing and commenting on and remixing videos, instead we are doing all of those same things with 3D-print files," said Darrell Hurt, a researcher at the National Institute of Allergy and Infectious Diseases who helped develop the 3D Print Exchange, speaking in a video from the NIH about the new site.
A 3D printer creates three-dimensional objects from digital models by "printing" material (such as plastic or metal) one layer at a time.
The NIH already uses 3D printing for a number of purposes, including making special lab equipment and creating anatomy models that doctors can then use to plan medical procedures. Scientists who study very small things, such as proteins, bacteria or viruses, can also enhance their understanding by creating 3D models.
"A researcher who's been using a computer model of this for 15 years learns something as soon as they put their hands on a real, tangible model," Hurtsaid in the video, referring to a 3D-printed representation of a protein.
All of the files on the site are free, and the site also features a tutorial for new users.
The library is not intended only for professional scientists. "We want this to be a place where people from all different walks of life can come together and download and share," Hurt said. "Who knows what some kid somewhere might come up with in using some of the 3D-modeling software, and then share that model out, and someone half a world away may learn something."