Dr. Putkis shows off different components of the machine, which includes an ultrasonic array, mounted camera, and laser. At a glance it looks like a desktop 3D printer, but this is no extrusion-based technology. The proof of concept demonstrated is a non-contact assembly of a printed circuit board (PCB) which itself isn’t so much 3D printed as it is put together — but this initial showing is not all that Neurotechnology has up its research sleeves.
Below is Dr. Putkis’ introduction to ultrasonic manipulation technology, with a look at the prototype machine and its capability in non-contact creation:
So what are they planning? Dr. Putkis answers A Few Questions For us to fill us in more about this patent-pending technology.
What inspired work with ultrasonic manipulation technology for use with 3D printing technology?
“We were intrigued by the versatility of ultrasonic manipulation. As it is a non-contact handling method, it is possible to manipulate materials and components that have very different mechanical properties and shapes, not to mention its ability to handle small or sensitive components. We saw the opportunity to use this technology to build a ‘universal ultrasonic gripper’ that would improve 3D printing technology.”
What can you tell us about the new 3D printing technology?
“The new technology will employ ultrasonic manipulation for positioning various components (such as electronic components) and/or depositing material (such as plastics). This will enable the development of more general and versatile printers, that are capable of, say, printing whole electronic devices.”
How does 3D printing incorporating ultrasonic technology compare with existing 3D printing techniques?
“Current 3D printing techniques can only print the particular material they are designed for. We believe that ultrasonic manipulation technology will enable the creation of printers that can not only deposit certain materials but also assemble electronic circuits or deposit a wide range of materials. In other words, it would add versatility to the 3D printers. However, things like printing speed, component welding and dispensing approaches need to be addressed and researched before such a technology could be applied in the 3D printing process.”
Dr. Osvaldas Putkis
What have you created using this method so far? What kinds of applications will this extend to?
“We have built an early prototype that can assemble simple electronic circuits. An array of ultrasonic transducers is used for non-contact transportation and positioning of electronic components and a laser is used to solder those components to a PCB board, also in a non-contact way. An on-board camera is used to coordinate the whole process, detect the PCB and component positions, calibrate the laser, etc. Currently, the prototype is a technology-demonstrator and can only handle components that are not smaller than approx 0.5mm. However, if higher frequency ultrasonic waves would be used, even the smallest electronic components could be manipulated. This is a challenge for pick-and-place machines and will probably become an even a bigger issue as the size of electronic components continues to shrink in the future. However, if we want to create a more general printer, we still need to implement the deposition process of other materials or components.”
Will this technology eventually be commercialized?
“There is still a lot of research and development to be done before this technology will find its way to end-user products. We are seeking partnerships that would help speed up the development and commercialization of this technology.”
As partnerships remain a key path forward for many in the 3D printing industry, we’ll be interested to follow along with any future collaborations that move ultrasonic manipulation further into 3D printing. Share your thoughts in the Neurotechnology forum at 3DPB.com.
[All images: Neurotechnology via YouTube screenshot]