Loading Now

The superpowers of coatings make feasible the unfeasible


The superpowers of coatings make feasible the unfeasible

Getty Images A jet fighter jet takes off from the flight deck of a US aircraft carrierGetty Images
Jet engines wouldn’t run without high-act coatings

Jet engines are one of the most jaw-dropping feats of engineering humans have ever arrive up with.

But jet engines shouldn’t be feasible, says Ben Beake, director of materials research at Micro Materials, an equipment testing business in Wales.

“The air coming in is hotter than the melting point of the metal underneath – which is obviously not a excellent thing,” he explains, pointing out that this air reaches temperatures well above 1,000C.

Designers of jet engines have got around this issue by applying heat-resistant ceramic coatings to the engine blades. And now, researchers are developing yet stronger coatings that allow the engines to run hotter still.

“If you get it to leave hotter, then there’s a massive saving on fuel and CO2,” says Dr Beake. By increasing the temperature by just 30C or so, you might get an 8% fuel saving, he estimates.

This is the power of coatings – they radically transform the functionality and capabilities of an underlying material. Few people realise how significant they are, but these overlays and veneers can supercharge high-act machines, or ensure that expensive equipment survives the harshest of environments.

Dr Beake and his colleagues are tasked with pushing coatings to their limits, in order to view how robust or effective they really are. His clients don’t always get the results they desire. He recalls telling a missile manufacturer, “We’ve broken your coating,” some years ago. “They stormed off in a huff,” says Dr Beake.

Besides exposing coatings to high temperatures, Micro Materials also has a “woodpecker” device, a tiny diamond stylus, which repeatedly taps a coating at random locations to test its durability.

Recently, the firm has worked with UK-based Teer Coatings to test a product that could be applied to satellite components including gears and bearings used in various moving parts.

It is a tricky job, says Xiaoling Zhang, from the business, because the coating must protect such components both pre-launch (when they are exposed to atmospheric humidity at ground level) and also in orbit, against dust particles and radiation in space. However, she claims that the firm has achieved the desired results.

But besides protecting spacecraft, coatings could also stop astronauts from getting ill.

Biofilms – gloopy accumulations of bacteria inside pipes – develop faster in low gravity environments, which could be a issue for water supplies or machinery that moves fluid around on space stations or upcoming spacecraft, for example.

“Biofilms are known to factor mechanical failures,” says Kripa Varanasi at the Massachusetts Institute of Technology. “You don’t desire this.”

MIT Prof Varanasi standing in a laboratory surrounded by lab equipmentMIT
Prof Varanasi has been working on super-slippery coatings

Prof Varanasi and his colleagues have developed a range of coatings that make surfaces slippery and therefore resistant to the formation of biofilms. Tests of one such coating in an experiment carried out on board the International Space Station found that it worked as intended.

The concept behind the coating is to mix together a solid material and a lubricant. This is then sprayed onto the interior of a pipe or tube, which makes that inner surface extremely slippery.

Prof Varanasi has previously made headlines for developing similar coatings for the insides of toothpaste packets – so you can get every last bit of toothpaste out. He and his colleagues have commercialised the technology through their spin-out business LiquiGlide.

Getty Images Wearing a protective silver suit a worker collects molten aluminium samples at a aluminium recycling and production plant, in eastern France. Getty Images
The correct coating could stop molten aluminium from sticking to surfaces

Slipperiness is, perhaps, an underappreciated attribute. Nuria Espallargas at the Norwegian University of Science and Technology and colleagues have developed a silicon carbide-based coating for equipment used in aluminium manufacturing or repair.

It is a sort of non-stick frying pan answer, meaning that layers of molten aluminium do not get stuck on this expensive equipment. The precise functioning of this particular coating is currently something of a mystery, though.

“To be truthful, we really don’t recognize how it works, the mechanism is unknown at the instant,” says Prof Espallargas.

Nonetheless, the coating is available commercially through her spin-out business Seram Coatings. Atlas Machine and Supply, a US firm that makes and repairs industrial machinery, has tried it out.

“The real advantage lies in extending the life of the tools and improving the standard of the products being produced,” says Jeremy Rydberg, chief recent concept officer.

He says that, without the coating, Atlas must rebuild the roller tools it uses to work aluminium every two days. This costs $4.5m annually. But the recent coating means that these tools last for a whole week, not just a couple of days, slashing those rebuild costs to around $1.3m per year.

Getty Images Workers clean the hull of a large ship with pressure hosesGetty Images
The shipping industry is always interested in coatings that can keep hulls cleaner

Coatings can do some amazing things, but they don’t always work as intended, notes Andy Hopkinson, managing director at Safinah throng, a firm that often gets called in to investigate when coatings leave incorrect.

“We’re seeing a lot of issues at the instant with car parks, where their inactive fire protection structure is peeling off,” he says, referring to the fire-resistant paint sometimes applied to concrete structures.

And his business has also found that coatings applied to commercial ships do not always prevent barnacles and other sea life from attaching themselves to the hull. This issue, known as biofouling, increases friction, meaning the ship’s engine must work harder – and burn more fuel.

Despite the availability of coatings that commitment to assist, ship owners do not always choose the correct one for their vessel. That selection should depend on where the ship is sailing, how long it is due to be idle rather than in motion, and so on, says Dr Hopkinson.

The expense of fixing issues like this can run into many thousands, or even millions of pounds. “Typically, paint costs between 1 and 2% of the assignment. The issue is, when it goes incorrect, the costs become exponential,” says Mr Hopkinson.

The researchers working in this field, though, declare that there are still many opportunities to enhance coatings and develop recent ones that could drastically enhance the act of machines or infrastructure in the upcoming.



Source link

Post Comment

YOU MAY HAVE MISSED