Featured Product
This Week in Quality Digest Live
Innovation Features
Ian Wright
MIT and ETH Zurich engineers use computer vision to help adjust material deposition rates in real time
Having more pixels could advance everything from biomedical imaging to astronomical observations
Chris Caldwell
Significant breakthroughs are required, but fully automated facilities are in the future
Leah Chan Grinvald
Independent repair shops are fighting for access to vehicles’ increasingly sophisticated data
Adam Zewe
How do these systems differ from other AI?

More Features

Innovation News
Exploring how a high-altitude electromagnetic pulse works
High-capacity solution using TSMC’s 3DFabric technologies
EcoBell paints plastic parts with minimal material consumption
Study of intelligent noise reduction in pediatric study
Easy to use, automated measurement collection
A tool to help detect sinister email
Funding will scale Aigen’s robotic fleet, launching on farms in spring 2024
High-end microscope camera for life science and industrial applications

More News

Kaya Wiles


Metal Too ‘Gummy’ to Cut? Draw on It With a Sharpie

A surprisingly low-tech solution to a long-standing nuisance

Published: Tuesday, August 7, 2018 - 11:01

Your everyday permanent markers, glue sticks, and packing tape may offer a surprisingly low-tech solution to a long-standing nuisance in the manufacturing industry: Making soft and ductile, or so-called “gummy” metals easier to cut.

What makes inks and adhesives effective isn’t their chemical content, but their stickiness to the surface of any gummy metal such as nickel, aluminum, stainless steels, or copper, researchers at Purdue University and the University of West Florida find in a study recently published in Physical Review Applied.

These adhesives help achieve a smoother, cleaner, and faster cut than current machining processes, which affects applications ranging from the manufacturing of orthopedic implants and surgical instruments to aerospace components.

Purdue researchers have discovered a simple solution for cutting soft gummy metals (left) just as cleanly and easily as hard metals (right). (Purdue University image/Anirudh Udupa)

 “A wide range of products rely on the machining of gummy metals,” says James Mann, assistant professor of mechanical engineering at the University of West Florida. “These could be something we use every day, such as the valve in a sink faucet, or something more critical, like a compressor part in the jet engine of an airplane.”

If a significant improvement can be made to the “machinability” of gummy metals or alloys—which is how well they cut, drill, or grind—then there is potential to lower the cost of products, improve their performance, or enable new and improved designs.

“Gummy metals characteristically deform in a very wiggly manner,” says Srinivasan Chandrasekar, Purdue professor of industrial engineering. “This wiggly flow involves significant energy consumption, which means that these metals require more force to machine than even some hard metals. We needed to find a way to suppress this wiggly flow.”

Getting rid of the wiggles means that the metal now tends to act more like a brittle ceramic or glass in the spot where it needs to be cut.

One well-known way to make the gummy metal brittle is by coating it with a suitable liquid metal, such as gallium in the case of aluminum. Liquid metals like these, however, tend to work too well, diffusing through the surface and causing the whole metal to crumble into a powder.

“This makes the metal being machined unusable,” says Chandrasekar.

Other attempts that met with limited success tended to be either toxic or result in tears and cracks on the machined surface. The researchers then began to explore other benign chemical media that would cut cleaner.

Marking with ink or attaching any adhesive on the metal’s surface dramatically reduced the force of cutting without the whole metal falling apart, leaving a clean cut in seconds. The quality of the machined surface also greatly improved.

Stickiness didn’t initially stand out as a solution that permanent markers, glue sticks, and tape have in common.

“We looked at the chemical ingredients of the permanent ink, isolated each of those on the metal’s surface, and there was no noticeable effect,” says Anirudh Udupa, lead author on the study and a post-doctoral researcher in Purdue’s School of Industrial Engineering. “So we realized that it’s not a particular chemical but the ink itself sticking to the metal through a physical adsorption mechanism.”

Purdue researcher Anirudh Udupa shows how marking a gummy metal’s surface with an ink or adhesive dramatically reduces the force required to cut it. (Purdue University image/Erin Easterling)

The Sharpie and adhesives also appeared to work on many gummy metals, regardless of the cutting tool.

“In hindsight, we can tell you why certain things weren’t successful in previous work,” says Koushik Viswanathan, Purdue post-doctoral researcher in industrial engineering. “It all comes back to the existence of this wiggly flow. Some people might have been trying to cut copper, for example, that was in the hard state rather than in the soft state.”

To the researchers’ knowledge, using permanent markers, glues, or tape to make gummy metals easier to machine does not pose any environmental hazards.

Next, Chandrasekar’s group will be assessing the degree of stickiness that works best for cutting gummy metals and exploring ways to advance the application of this technology into industrial practice.

This research is supported by the U.S. Army Research Office (W911NF-15-1-0591), the National Science Foundation (CMMI 1562470 and DMR 1610094), and the U.S. Department of Energy (DE-EE0007868).


About The Author

Kaya Wiles’s picture

Kaya Wiles

Kayla Wiles is an engineering sciences writer at Purdue University.