Thursday, 24 April 2014
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Device detects hidden damage in composite aircraft materials

In recent years, many manufacturers have started building their aircraft from advanced composite materials, which consist of high-strength fibres, such as carbon or glass, embedded in a plastic or metal matrix.

Such materials are stronger and more lightweight than aluminium, but they are also more difficult to inspect for damage, because their surfaces usually do not reveal underlying problems.

‘With aluminium, if you hit it, there’s a dent there. With a composite, oftentimes if you hit it, there’s no surface damage, even though there may be internal damage,’ said Brian Wardle, associate professor of aeronautics and astronautics at MIT.

Wardle and his colleagues have devised a new way to detect that internal damage, using a simple handheld device and heat-sensitive camera. Their approach also requires engineering the composite materials to include carbon nanotubes, which generate the heat necessary for the test.

One method that inspectors now use to reveal damage in advanced composite materials is infrared thermography, which detects infrared radiation emitted when the surface is heated. In an advanced composite material, any cracks or delamination (separation of the layers that form the composite material) will redirect the flow of heat. That abnormal flow pattern can be seen with a heat-sensitive (thermographic) camera.

This is effective but cumbersome, because it requires large heaters to be placed next to the surface, Wardle said. With his new approach, carbon nanotubes are incorporated into the composite material. When a small electric current is applied to the surface, the nanotubes heat up, eliminating the need for any external heat source. The inspector can see the damage with a thermographic camera or goggles.

‘It’s a very clever way to use the properties of carbon nanotubes to deliver that thermal energy, from the inside out,’ said Douglas Adams, associate professor of mechanical engineering at Purdue University. Adams, who was not involved in the research, notes that two fundamental challenges remain: developing a practical way to manufacture large quantities of the new material, and ensuring that the addition of nanotubes does not detract from the material’s primary function of withstanding heavy loads.

The carbon-nanotube hybrid materials that Wardle is developing have so far shown better mechanical properties, such as strength and toughness, than existing advanced composites.

The project is part of a multi-year, aerospace-industry-funded effort to improve the mechanical properties of existing advanced aerospace-grade composites. The US Air Force and Navy are also interested in the technology and Wardle is working with them to develop it for use in their aircraft and vessels.

Infrared themographic image of a nanoengineered composite heated via electrical probes (clips can be seen at bottom of image). The scalebar of colours is degrees Celsius. The MIT logo has been machined into the composite, and the hot and cool spots around

Infrared themographic image of a nanoengineered composite heated via electrical probes (clips can be seen at bottom of image). The scalebar of colours is degrees Celsius. The MIT logo has been machined into the composite, and the hot and cool spots around the logo are caused by the thermal-electrical interactions of the resistive heating and the logo ’damage’ to the composite

 

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