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NASA Targets 2024 for First Flight of X-59 Experimental Aircraft


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NASA Targets 2024 for First Flight of X-59 Experimental Aircraft

X-59 being moved from the construction site.
NASA’s X-59 research aircraft moved from its construction site to the flight line — or the space between the hangar and the runway — at Lockheed Martin Skunk Works in Palmdale, California on June 16, 2023. The move allowed the X-59 team to perform safety and structural testing, critical steps toward first flight.
Lockheed-Martin

NASA’s Quesst mission has adjusted the scheduled first flight of its X-59 quiet supersonic aircraft to 2024.

A one-of-a-kind experimental aircraft, the X-59 has required complex engineering from NASA researchers working with prime contractor Lockheed Martin Skunk Works. In addition to the aircraft’s design, the X-59 also combines new technology with systems and components from multiple, established aircraft, such as its landing gear from an F-16 and its life-support system adapted from an F-15.

As part of the demands of developing this unique aircraft, the Quesst team is working through several technical challenges identified over the course of 2023, when the X-59 had been scheduled to make its first flight.  Extra time is needed to fully integrate systems into the aircraft and ensure they work together as expected. The team is also resolving intermittent issues with some of the safety-redundant computers that control the aircraft’s systems.

Quesst made steady progress toward flight over the past year. The team installed the finishing touches to the X-59’s tail structure, which allowed them to finalize its electrical wiring and proceed to critical ground tests, and moved it from its assembly facility to the flight line to perform structural testing.

The X-59 will demonstrate the ability to fly supersonic, or faster than the speed of sound, while reducing the normally loud sonic boom to a quiet sonic thump. NASA plans to fly the X-59 over several communities to gather data on how people perceive the sound it produces. The agency will provide that information to U.S. and international regulators to potentially adjust rules that currently prohibit commercial supersonic flight over land.

NASA’s top priorities for any mission are safety and ensuring success. For Quesst, that means not only being sure that the X-59 is safe before it flies, but safe in the long term and reliable during the community test phase. The aircraft is currently undergoing integrated testing, which must be completed before it flies. Once that stage is complete, the aircraft will continue its journey with a flight readiness review, at which point NASA plans to release a more specific timeline for first flight.

Quesst is a mission with the potential to revolutionize commercial aviation travel by dramatically reducing travel time. Safely and reliably flying the X-59 is critical for NASA to achieve those benefits. The agency is committed to a thorough review and testing process that results in the success of that mission.

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      An E-3 Test Facility was constructed to support various component and small/subscale engine and booster test projects. Relativity Space leased a partially developed E-4 test area in 2018 and has since completed construction to support its commercial testing.
      All in all, the E Test Complex stands feature 12 active cells capable of various component and engine testing. The versatility of the complex infrastructure and test team allows it to support test projects for a range of commercial aerospace companies, large and small. Currently, both E-2 cells 1 and 2 are leased to Relativity Space through 2028.
      An aerial image shows the E-1 Test Stand at NASA’s Stennis Space Center on May 19, 2015. The versatile four-stand E Test Complex includes 12 active test cell positions capable of various component, engine, and stage test activities. NASA/Stennis An aerial image shows the E-3 test area at NASA’s Stennis Space Center on May 19, 2015. The versatile four-stand E Test Complex includes 12 active test cell positions capable of various component, engine, and stage test activities. NASA/Stennis An aerial image shows the E-2 Test Stand (Cell 1) at NASA’s Stennis Space Center on May 19, 2015. The versatile four-stand E Test Complex includes 12 active test cell positions capable of various component, engine, and stage test activities. NASA/Stennis “These facilities really do not exist anywhere else in the United States,” said Kevin Power, assistant director, Office of Project Management in the NASA Stennis Engineering and Test Directorate.  “Customers come to us with requirements for certain tests of an article, and we look at what is the best place to test it based on the facility infrastructure. We have completed component level testing, all the way up to full engines.”
      The list of companies who have conducted – or are now conducting – propulsion projects in the E Test Complex reads like a who’s who of commercial aerospace leaders.
      “The E Complex illustrates the NASA Stennis story,” Power said. “We have very valuable infrastructure and resources, chief of which is the test team, who adapt to benefit NASA and meet the needs of the growing commercial aerospace industry.”
      For information about NASA’s Stennis Space Center, visit:
      Stennis Space Center – NASA
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      Last Updated Nov 13, 2024 EditorNASA Stennis CommunicationsContactC. Lacy Thompsoncalvin.l.thompson@nasa.gov / (228) 688-3333LocationStennis Space Center Related Terms
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