Shape memory alloy allows for foldable wings without actuators

Nasa has successfully applied a new technology in flight that allows aircraft to fold their wings to different angles while in the air.

The recent flight series, which took place at Nasa’s Armstrong Flight Research Center in California, was part of the Spanwise Adaptive Wing project, or SAW. This project aims to validate the use of a cutting-edge, lightweight material that is able to fold the outer portions of aircraft wings and their control surfaces to optimal angles in flight.

SAW, which is a joint effort between Armstrong, Nasa’s Glenn Research Center in Cleveland, Langley Research Center in Virginia, Boeing Research and Technology in St Louis and Seattle, and Area-I in Georgia, may produce multiple in-flight benefits to aircraft in the future, both subsonic and supersonic.

Folding wings in flight is an innovation that had been studied using aircraft in the past, including the North American XB-70 Valkyrie in the 1960s. However, the ability to fold wings in flight has always been dependent on heavy and bulky conventional motors and hydraulic systems, which can be cumbersome to the aircraft.

The SAW project intends to obtain a wide spectrum of aerodynamic benefits in flight by folding wings through the use of an innovative, lightweight material called shape memory alloy. This material is built into an actuator on the aircraft, which plays a vital role for moving parts on the airplane, where it has the ability to fold the outer portion of an aircraft’s wings in flight without the strain of a heavy hydraulic system. Systems with this technology may weigh up to 80% less than traditional systems.

The recent series of flight tests at Armstrong successfully demonstrated the material’s application and use, by folding the wings between 0 and 70° up and down in flight.

“We wanted to see: can we move wings in flight, can we control them to any position we want to get aerodynamic benefits out of them, and could we do it with this new technology,” says SAW co-principal investigator Othmane Benafan. “Folding wings has been done in the past, but we wanted to prove the feasibility of doing this using shape memory alloy technology, which is compact, lightweight, and can be positioned in convenient places on the aircraft.”

On subsonic aircraft, such as commercial airliners, the potential aerodynamic benefit of folding the wings includes increased controllability, which may result in a reduced dependency on heavier parts of the aircraft, including the tail rudder. This may result in a more fuel-efficient aircraft, as well as the ability for future long-winged aircraft to taxi in airports. Additionally, pilots may take advantage of a number of different flight conditions, such as wind gusts, by folding their wings to adapt to any particular condition experienced in flight.

One of the most significant potential benefits of folding wings in flight, however, is with supersonic flight.

“There’s a lot of benefit in folding the wing tips downward to sort of ‘ride the wave’ in supersonic flight, including reduced drag,” says SAW principal investigator Matt Moholt. “This may result in more efficient supersonic flight.

“Through this effort, we may be able to enable this element to the next generation of supersonic flight, to not only reduce drag but also increase performance, as you transition from subsonic to supersonic speeds. This is made possible using shape memory alloy.”

The shape memory alloy is triggered by temperature, and works by using thermal memory in a tube to move and function as an actuator. Upon being heated, the alloy would activate a twisting motion in the tubes, which ultimately moves the wing’s outer portion up or down.

Nasa Glenn, which developed the initial alloy material, worked closely with Boeing to be able to use the alloy with an actuator in flight.

“The performance of this new alloy that we developed between Nasa and Boeing really showed outstanding performance,” says Jim Mabe, technical fellow with Boeing Research and Technology. “From the time we started initial testing here at Boeing, up to the flight tests, the material behaved consistently stable, and showed a superior performance to previous materials.”

To test the technology, Nasa turned to Area-I to design, build and operate a remotely-controlled flight testbed called Prototype Technology Evaluation Research Aircraft, or PTERA.

Area-I was also involved in the design and integration of a shape memory alloy-actuated, wing-folding mechanism for the aircraft. The small-scale UAV features extensive flight instrumentation for gathering data on SAW, as well as the ability to accommodate newly-designed wings for testing.

Area-I chief executive officer Dr Nicholas Alley, says: “The intentional, in-flight actuation of the outboard wing panels was a historic event, made all the more special as it took place over Rogers Dry Lake, where so much aviation history has been written.”

Including a pair of system safety check flights, the SAW test flights were conducted over a two-day period. PTERA took off from the Rogers Dry Lake at Edwards Air Force Base with its wings at a level, zero-degree deflection. The testbed was flown in a large ‘racetrack’ pattern, providing long legs of flight in which the necessary manoeuvres for the research could be done. During these manoeuvres, onboard controllers heated and cooled the SAW actuators, folding the wing panels to different angles between 0 and 70°.

For the first two flights, the wing tips were rigged to fold downward, while later flights featured rearranging the hardware to achieve 70° upward deflection. Wing folding manoeuvres were achieved in flight within three minutes each.

Further flights are planned for as early as summer 2018 that will expand the functionality of the SAW system, to be able to fold wings 70° both up and down in a single flight. Tests are also expected to take place at Glenn, where engineers are working to scale up the technology flown on PTERA to be used on the wing of an F-18.

“We put the SAW technology through a real flight environment, and these flights not only proved that we can fly with this technology, but they validated how we went about integrating it,” says Moholt. “We will use the data from these flights to continue to improve upon the actuation system, including speed and smoothness of folding the wings, and we’ll apply them as we get ready to fly again in 2018.”

Engineering Materials

This material is protected by MA Business copyright
See Terms and Conditions.
One-off usage is permitted but bulk copying is not.
For multiple copies contact the sales team.


Supporting Information
Do you have any comments about this article?

Your comments/feedback may be edited prior to publishing. Not all entries will be published.
Please view our Terms and Conditions before leaving a comment.

© MA Business Ltd (a Mark Allen Group Company) 2022