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NASA Wind Tunnel Tests Lockheed Martin’s X-Plane Design for a Quieter Supersonic Jet

Supersonic passenger airplanes are another step closer to reality as NASA and Lockheed Martin began the first high-speed wind tunnel tests for the Quiet Supersonic Technology, or QueSST, X-plane preliminary design here at NASA’s Glenn Research Center. In this time-lapse, engineers assemble a scale model of the design and install it in Glenn’s 8’ x 6’ Supersonic Wind Tunnel. Over the next eight weeks, engineers will expose the model to wind speeds ranging from Mach 0.3 to 1.6 to understand the aerodynamics of the X-plane design as well as aspects of the propulsion system. Credits: NASA

Supersonic passenger airplanes are another step closer to reality as NASA and Lockheed Martin begin the first high-speed wind tunnel tests for the Quiet Supersonic Technology (QueSST) X-plane preliminary design at NASA’s Glenn Research Center in Cleveland.

The agency is testing a nine percent scale model of Lockheed Martin’s X-plane design in Glenn’s 8’ x 6’ Supersonic Wind Tunnel. During the next eight weeks, engineers will expose the model to wind speeds ranging from Mach 0.3 to Mach 1.6 (approximately 150 to 950 mph) to understand the aerodynamics of the X-plane design as well as aspects of the propulsion system. NASA expects the QueSST X-plane to pave the way for supersonic flight over land in the not too distant future.

“We’ll be measuring the lift, drag and side forces on the model at different angles of attack to verify that it performs as expected,” said aerospace engineer Ray Castner, who leads propulsion testing for NASA’s QueSST effort. “We also want to make sure the air flows smoothly into the engine under all operating conditions.”

Mechanical technician Dan Pitts prepares a nine percent scale model of Lockheed Martin’s Quiet Supersonic Technology (QueSST)
Mechanical technician Dan Pitts prepares a nine percent scale model of Lockheed Martin’s Quiet Supersonic Technology (QueSST) X-plane preliminary design for its first high-speed wind tunnel tests at NASA’s Glenn Research Center in Cleveland. Credits: NASA

The Glenn wind tunnel is uniquely suited for the test because of its size and ability to create a wide range of wind speeds.

“We need to see how the design performs from just after takeoff, up to cruising at supersonic speed, back to the start of the landing approach,” said David Stark, the facility manager. “The 8-by-6-foot supersonic wind tunnel allows us to test that sweet spot range of speeds all in one wind tunnel.”

Recent research has shown it is possible for a supersonic airplane to be shaped in such a way that the shock waves it forms when flying faster than the speed of sound can generate a sound at ground level so quiet it will hardly will be noticed by the public, if at all.

“Our unique aircraft design is shaped to separate the shocks and expansions associated with supersonic flight, dramatically reducing the aircraft’s loudness,” said Peter Iosifidis, QueSST program manager at Lockheed Martin Skunk Works. “Our design reduces the airplane’s noise signature to more of a ‘heartbeat’ instead of the traditional sonic boom that’s associated with current supersonic aircraft in flight today.”

According to Dave Richwine, NASA’s QueSST preliminary design project manager, “This test is an important step along the path to the development of an X-plane that will be a key capability for the collection of community response data required to change the rules for supersonic overland flight.”

NASA awarded Lockheed Martin a contract in February 2016 for the preliminary design of a supersonic X-plane flight demonstrator. This design phase has matured the details of the aircraft shape, performance and flight systems. Wind tunnel testing and analysis is expected to continue until mid-2017. Assuming funding is approved, the agency expects to compete and award another contract for the final design, fabrication, and testing of the low-boom flight demonstration aircraft.

The QueSST design is one of a series of X-planes envisioned in NASA’s New Aviation Horizons (NAH) initiative, which aims to reduce fuel use, emissions and noise through innovations in aircraft design that depart from the conventional tube-and-wing aircraft shape. The design and build phases for the NAH aircraft will be staggered over several years with the low boom flight demonstrator starting its flight campaign around 2020, with other NAH X-planes following in subsequent years, depending on funding.

For more information about QueSST, visit:

http://www.lockheedmartin.com/us/products/QueSST0.html

For more information about NASA’s aeronautics research, visit:

http://www.nasa.gov/aero

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J.D. Harrington
Headquarters, Washington
202-358-5241
j.d.harrington@nasa.gov
Jan Wittry
Glenn Research Center, Cleveland
216-433-5466
jan.m.wittry-1@nasa.gov
Erica Turner
Lockheed Martin Communications
661-572-6263
erica.r.turner@lmco.com