Featured Product
This Week in Quality Digest Live
Innovation Features
Jennifer Chu
High-speed experiments help identify lightweight, protective ‘metamaterials’
Michael King
Augmenting and empowering life-science professionals
Rich Nobliski
Helping narrow the manufacturing skills gap with 3D tech
NIST
NIST scientists perfect miniaturized technique
Kristi McDermott
Technology and what the future requires for patients and providers to thrive

More Features

Innovation News
New tool presents precise, holistic picture of devices, materials
Enables better imaging in small spaces
Helping mines transform measurement of blast movement
Handles materials as thick as 0.5 in., including steel
For companies using TLS 1.3 while performing required audits on incoming internet traffic
Accelerates service and drives manufacturing profitability
Process contains leaks, improves thermal performance in buildings
Delivered by SpaceX launch to demonstrate in-space capabilities
Recognized among early adopters as a leading innovation for the life sciences industry

More News

Ian Wright

Innovation

New 3D-Printing Materials and Faster Speeds With In-Process Monitoring

MIT and ETH Zurich engineers use computer vision to help adjust material deposition rates in real time

Published: Thursday, December 7, 2023 - 12:02

Curing time is the Achilles heel of multimaterial 3D printing. Typically, a multimaterial 3D printer uses thousands of nozzles to deposit resins, which are then smoothed with a scraper or roller before being cured with ultraviolet (UV) light. As a result, this process is constrained by how quickly the resins cure. This limits the types of materials that can be 3D printed.

Now, engineers from MIT, ETH Zurich, and the startup Inkbit have developed a new system that uses computer vision to monitor the printing process and adjust deposition rates to ensure material consistency across each layer of a build. Because the system replaces the need for smoothing or scraping, it can work with materials that cure more slowly than the acrylates most commonly used in 3D printing. These include thiol-based materials, which cure more slowly than acrylates but are also more elastic, more stable over a wider range of temperatures, and don’t degrade as quickly when exposed to sunlight.

Moreover, the automatic adjustments make 3D printing on the new system faster than comparable production-grade systems that need to pause or slow down to adjust for curing times. How much faster? Approximately 660 times, according to the researchers.

The system itself involves four high-frame-rate cameras and two lasers that continuously scan the print surface. The computer vision system converts the scans and camera images into a high-resolution depth map, compares it to the CAD model of the part being printed, and adjusts the deposition rate accordingly.

“Geometrically, it can print almost anything you want made of multiple materials,” says Robert Katzschmann, assistant professor of robotics at ETH Zurich, in a press release. “There are almost no limitations in terms of what you can send to the printer, and what you get is truly functional and long-lasting.” 

Using this method, the team has been able to 3D-print complex robotic devices that combine soft and rigid materials, such as robotic grippers modeled like the human hand with artificial bones, ligaments, and tendons.

“Our key insight here was to develop a machine-vision system and completely active feedback loop,” says Wojciech Matusik, professor of electrical engineering and computer science at MIT. “This is almost like endowing a printer with a set of eyes and a brain, where the eyes observe what is being printed, and then the brain of the machine directs it as to what should be printed next.”

This research was developed using MIT’s MultiFab, which introduced the ability to 3D-print with up to 10 different materials simultaneously. By introducing a contactless process, the researchers have further added to the number of materials that can be printed on the MultiFab.

The researchers are now looking at using the system to print with hydrogels, which are used in tissue-engineering applications, as well as silicon materials, epoxies, and special types of durable polymers.

Their research is published in the journal Nature.

Published Nov. 15, 2023, on engineering.com.

Discuss

About The Author

Ian Wright’s picture

Ian Wright

Ian Wright is a philosopher-turned-writer with bachelor’s and master’s degrees in philosophy from McMaster University. He spent six years working on his doctoral dissertation on mindreading (seriously) at York University before withdrawing in good standing in 2015 to pursue a new career in the private sector. He is managing editor at engineering.com.