Four Technologies for Advancing Remanufacturing


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Recycling is a nice idea. But the energy burned shipping a used material, melting it down, and reforming it, keeps it from being a perfectly sustainable system. If we could cut out that middle part, and simply fix products, and return them to the condition they were in when new—and thereby double or triple their lifespans—we’d be doing the planet a lot more good.

Such rejuvenating of a product, and reissuing a good-as-new warranty, is a recent practice known as remanufacturing. And it doesn’t just help the planet. Manufacturers and endusers profit as well. “If we can remanufacture products, we can save huge in terms of material and energy costs,” says Nicholas Yeo, technical director at Singapore’s Advanced Remanufacturing and Technology Centre. When an excavator costs hundreds of thousands of dollars, a mining company doesn’t want to have to buy a new one every time a part breaks, even if it’s a major part. By remanufacturing it, Caterpillar will make money, and the mining company will save bundles. That it’s refurbished, and not actually knew, doesn’t bother them in the slightest. “They don't care. They know the business model works for them.”

The remanufacturing movement is already underway for large, high-end products like airplanes and excavators. They owe their ability to do so to recent advanced manufacturing techniques. Without them, remanufacturing simply wouldn’t be possible. And as these technologies improve, remanufacturing will become viable for more and more industries. Here Yeo points us to four technologies that are aiding the expansion of remanufacturing.

1) Laser Metal Deposition
Laser Metal Deposition is essentially a 3D printing technology. It uses a laser to melt powder or wire, be it titanium, nickel, cobalt, or a steel alloy, at a focal point into any shape on any surface. It can easily fill in a pitted, grooved, or otherwise worn surface, or entirely coat one, if need be. It allows parts to be fixed that would have previously required too much heat. “It isn’t new,” says Yeo. “Twenty years ago, GE was the first to use it. It didn't take off because of economy of scale, but right now things are coming down in cost.”

Robotic High Pressure Cold Spray tests at GE Global Research labs. Image: GE

 

 

2) Robotic High-Pressure Cold Spray 
Where laser metal deposition better controls the heat used to rebuild a surface, Robotic High-Pressure Cold Spray, as the name implies, abandons heat altogether. Cold spray technology fires tiny particles in a high-pressure air jet, at supersonic speeds at a substrate. They move so fast that they adhere to the surface without heat. “The beauty of it, is that it easily deposits five to ten kilograms in a couple of minutes—literally flying onto the part,” says Yeo. Marine and oil and gas companies can now salvage a five ton piece that previously would have been scrapped. The technology has allowed the U.S. Air Force (an early adopter) to repair sand-pitted helicopters that would have had otherwise been out of service.

3) Automated Adaptive Machining for Parts Repair
“If you 3D print 10 parts, you get 10 different distortions,” says Yeo. That doesn’t work too well for crucial, highly specified parts in say, an airplane. That’s where Automated Adaptive Machining for Parts Repair comes into play. With advanced scanning technology that scans at the micron level the injured part can be compared to the original. Then a tool path is generated which returns the part to its near-virgin state. In short, it removes the human element from repair.

4) Design for Remanufacturing
Design for manufacturing is certainly a useful concept, keeping costs down and production as efficient as possible by imagining the manufacturing process from the beginning of development. But Design for Remanufacturing takes it one step further. It asks designers to imagine not only how a product will be built, but how it will be rebuilt. With remanufacturing in mind, designers may change the materials, and coatings they chose, as well as the accessibility and layout of parts. Soon software will help designers make such an analysis. But first, of course, they have to know about it. In a sense, design for remanufacturing is an evangelical idea: Get the engineers of the world thinking about it, and remanufacturing will have a bigger chance of reducing waste.

Michael Abrams is an independent writer.

   
If we can remanufacture products, we can save huge in terms of material and energy costs.

Nicholas Yeo, Singapore’s Advanced Remanufacturing and Technology Centre

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August 2017

by Michael Abrams, ASME.org