Researchers at Pacific Northwest National Laboratory have developed and successfully tested a novel process – called Friction Stir Dovetailing – that joins thick plates of aluminium to steel. The new process will be used to make lighter-weight military vehicles that are more agile and fuel efficient. The April 15 issue of Scripta Materialia describes the process in detail and the testing of joints created using the new technique. The peer-reviewed journal covers original research on the relationship between the structure and properties of materials.
Lightening the tank
According to the U.S. Government Accountability Office, the military spends several billion dollars each year on fuel consumption, which could be reduced by lessening the weight of ships, aircraft, ground vehicles, and cargo. To lower fuel costs and increase operational effectiveness while still maintaining the safety of military personnel, the U.S. Army Tank Automotive Research Development and Engineering Centre – or TARDEC – launched a campaign in 2014 seeking ways to make combat systems – such as tanks, fighting vehicles, and personnel carriers – more lightweight. One approach they are investigating is the replacement of heavy steel components with thicker, yet lighter, aluminium. But aluminium and steel cannot be welded together due to vastly different melting points, so they sought a new process to join these materials. TARDEC joined forces with PNNL – which had previously developed unique material joining techniques for the automotive industry – to develop Friction Stir Dovetailing. These previous techniques included Friction Stir Welding to join similar metals of differing thickness, and Friction Stir Scribe, which joins thin sheets of significantly different materials, like aluminium and steel. While Friction Stir Scribe solved the challenge of joining thin sheets of aluminium with steel, that technique was found to not scale up to the thick plates of aluminium – measured in inches – needed for robust military vehicles. A technique that dovetails nicely with aluminium and steel. In woodworking, dovetails and glue are used to securely join pieces of wood together. Friction Stir Dovetailing is a similar approach for metals. Using a specially designed tool, aluminium is deformed into a steel dovetail groove to form a mechanical interlock. At the same time, the tool rubs along the bottom of the dovetail to form a thin metallurgical bond – or intermetallic compound – which “glues” the metals together within the dovetail. “The combination of mechanical interlocking and metallurgical bonding formed during a single process is the innovation that produces joints of superior strength and ductility compared to joints created by the other friction stir methods,” said PNNL engineer Scott Whalen, who leads the research. Lab testing of joints made by Friction Stir Dovetailing showed that, when combining metallurgical bonding with the dovetail configuration, the joint strength is not only superior, but the material can stretch to over a half centimetre before the joint breaks — illustrating five times more ductility than aluminium and steel joined with other friction stir techniques. The research team discovered that using complex machine controls to precisely regulate temperature and pressure at the aluminium-steel interface inhibited growth of intermetallic compounds. These compounds grow thick and non-uniformly during the other friction stir techniques, causing joint brittleness and failure. However, growth of intermetallic compounds – iron aluminide or Fe3Al – during the Friction Stir Dovetailing technique is beneficial to the joint because they are so thin, one thousand times thinner than a human hair, which acts as “glue” without causing embrittlement. “Intermetallic compounds will form between aluminium and steel during all friction stir techniques as part of the heating process,” said Whalen. “We discovered that Friction Stir Dovetailing inhibits intermetallic compound overgrowth because temperature and pressure are much lower than other friction stir approaches.” Lab testing of joints made by Friction Stir Dovetailing showed that when combining metallurgical bonding with the dovetail configuration, the joint strength is not only superior, but the material can stretch to over a half centimetre before the joint breaks – illustrating five times more ductility than aluminium and steel joined with other friction stir techniques. This allows the joint to “give” or move farther before breakage – an attractive feature for military combat vehicles. “We are constantly looking for innovative multi-material joining methods to help us select the right material for the right purpose in the right location, and Friction Stir Dovetailing offers us precisely such a state-of-the-art method,” said Jason Middleton, TARDEC associate director for Product Lifecycle Engineering. The research team now plans to refine the technique and expand the process for other joint configurations. In addition to aluminium and steel, other material combinations such as aluminium to copper, aluminium to magnesium, and magnesium to steel can also be joined using Friction Stir Dovetailing. And while Friction Stir Dovetailing will help solve the fuel consumption challenge for TARDEC, it is also available for licensing for other potential applications as well as collaborative research opportunities via PNNL commercialisation manager Sara Hunt.
Phys.org, 13 April 2018 ; http://phys.org