Jump to content

NASA’s X-59 Rollout Embodies Aeronautical Tradition


NASA

Recommended Posts

  • Publishers
5 Min Read

NASA’s X-59 Rollout Embodies Aeronautical Tradition

Artist’s concept of the X-59
Artist concept of the X-59 quiet supersonic aircraft. The centerpiece of NASA's Quesst mission, the agency and Lockheed Martin will formally unveil the aircraft to the public on Friday, Jan. 12.
Credits: NASA

Lee esta historia en español aquí.

NASA’s X-59 aircraft is heading out of the hangar – preparing to embark on the first phase of its mission to fly faster than the speed of sound without generating a loud sonic boom.

Leadership from NASA and prime contractor Lockheed Martin will officially unveil the fully completed and freshly painted X-59 to the world during a rollout ceremony Friday, Jan. 12 at 4 p.m., EST. NASA TV will broadcast the event live from Lockheed Martin’s Skunk Works facility in Palmdale, California, where the aircraft was assembled.

“This is the big reveal,” said Catherine Bahm, manager of NASA’s Low Boom Flight Demonstrator project, who is overseeing the development and build of the X-59. “The rollout is a huge milestone toward achieving the overarching goal of the Quesst mission to quiet the sonic boom.”

Quesst is NASA’s mission through which the X-59 will demonstrate its quiet supersonic capabilities. NASA will fly the aircraft over selected U.S. communities and then survey what people on the ground hear when it flies overhead. The agency will share data on these reactions to the quieter sonic “thumps” with regulators, who could then consider rules that currently ban commercial supersonic flight over land because of noise concerns.

Watch this two-minute video to experience a visual overview of NASA’s Quesst mission featuring the X-59 experimental aircraft.

Tradition of Rollout

So, what is an aircraft rollout? And why is it significant to NASA, industry stakeholders, and the team of aeronautical innovators who built the X-59?

Conceiving, designing, building, and testing a new airplane takes years of meticulous, highly detailed work. Every new design helps innovate a new way to fly – especially in the case of X-planes, whose very mission is to continue pushing the boundaries of what’s possible.

Unveiling the X-59 to the world represents not just the aircraft’s technical achievements, but also the future of flight, and the spirit of aeronautics research itself.

For the team, some of whom have worked on the aircraft since the first component was created, the reveal of the X-59 will be a very special moment.

CATHERINE BAHM

CATHERINE BAHM

NASA Project Manager

In the past, aircraft and spacecraft built for and used by NASA have had rollout ceremonies ranging in scope and meaning.

In 1959, for example, the first X-15 rocket-powered aircraft rolled out to great fanfare to an audience including project leadership, the aircraft’s pilots, and then-Vice President Richard Nixon. The aircraft represented the future of winged spaceflight and hypersonic flight. It went on to carry American pilots into space onboard a winged vehicle for the first time, as well as set the record for the fastest speed a human has travelled on an airplane, which still stands to this day.

Crowds gather to admire the first X-15 after its rollout from the North American Aviation plant
Crowds gather on Oct. 15, 1958, to admire the first X-15 rocket plane after its rollout from the North American Aviation plant in Los Angeles. One of NASA’s most historic aircraft, it flew 199 missions between 1959 and 1968 during a program that included NASA, the U.S. Air Force, and the U.S. Navy.

Another famous NASA rollout is that of space shuttle Enterprise in 1976 with the cast of Star Trek: The Original Series, and the show’s creator, Gene Roddenberry, in attendance. The Enterprise, so named for the fictional starship of the 1960s television series, proved the shuttle orbiter could descend and land like an airplane following reentry from space. The vehicle paved the way for the Space Shuttle Program to proceed with spaceflight.

a space shuttle orbiter named Enterprise sits behind NASA officials and actors from the TV series Star Trek.
NASA officials and representatives from the TV show Star Trek, including creator Gene Roddenberry, were on hand for Enterprise’s rollout from its Rockwell factory in Palmdale, California, on Sept. 17, 1976.
NASA

Culmination of Efforts

In the case of the X-59, the rollout ceremony provides a glimpse of a potential new era of high-speed commercial flight over land –  a quiet one.

Fifty years ago, the United States prohibited commercial supersonic flight over land  because of concerns about the noise generated by sonic booms. Today, however, Quesst’s technology could reduce this noise dramatically. The mission aims to gather data from the X-59 that could help regulators adjust the ban, basing revised rules on noise levels instead of speed.

“The idea of lifting the ban on supersonic flight over land is really exciting,” Bahm said. “And that’s the future the X-59 could enable.”

The rollout also represents something closer to the ground – the achievement of the hardworking, dedicated team who took the aircraft from imagination to reality. For them, the rollout celebrates the weeks, months, and years spent developing and building the X-59.

Watch this 57-second time-lapse video of the X-59’s assembly as it happened between May of 2019 and June of 2021 inside Lockheed Martin’s Skunk Works factory in Palmdale, California.

“For the team, some of whom have worked on the aircraft since the first component was created, the reveal of the X-59 will be a very special moment.” Bahm said. “The innovative design of the X-59 leverages decades of work for NASA. We are sharing this achievement with all those who made this possible.”

With assembly complete, NASA’s mission to quiet the boom reaches a new chapter. Though there’s still a ways to go, the potential future for commercial supersonic travel is closer than it was before. The Quesst mission team will now continue ground testing before first flight later this year.

“Rollout is a major accomplishment, but it also means the next milestone is first flight, and then supersonic flights after that,” Bahm said. “Our eyes are on the mission.”

A Boeing 747 Jumbo Jet is seen in a hangar with 26 flight attendants representing 26 airliner standing in front of the airplane.
A memorable rollout ceremony in aviation history took place on Sept. 30, 1968, when the first Boeing 747 made its public debut at the company’s Everett assembly plant near Seattle. To commemorate the event, flight attendants representing each of the 26 airlines who had purchased a 747 attended the ceremony.
Boeing

About the Author

John Gould

John Gould

Aeronautics Research Misson Directorate

View the full article

Link to comment
Share on other sites

Join the conversation

You can post now and register later. If you have an account, sign in now to post with your account.
Note: Your post will require moderator approval before it will be visible.

Guest
Reply to this topic...

×   Pasted as rich text.   Paste as plain text instead

  Only 75 emoji are allowed.

×   Your link has been automatically embedded.   Display as a link instead

×   Your previous content has been restored.   Clear editor

×   You cannot paste images directly. Upload or insert images from URL.

  • Similar Topics

    • By NASA
      4 min read
      Preparations for Next Moonwalk Simulations Underway (and Underwater)
      An artist’s concept of the X-66 aircraft Boeing will produce through NASA’s Sustainable Flight Demonstrator project. The aircraft, designed to prove the concept of more aerodynamic, fuel-efficient transonic truss-braced wings, is an example of the type of project model-based systems analysis and engineering will provide benefits to.Boeing As NASA continues cutting-edge aeronautics research, the agency also is taking steps to make sure the benefits from these diverse technologies are greater than the sum of their parts.
      To tackle that challenge, NASA is using Model-Based Systems Analysis and Engineering (MBSAE). This type of engineering digitally simulates how multiple technologies could best work together as a single, complex system. It is performed using advanced digital tools and computing programs.
      The goal: Optimize the next generation of 21st-century aviation technology.
      Model Benefits
      “MBSAE provides a way to envision how all these technologies, being developed separately, can all fit together in the end,” said Eric Hendricks, who leads MBSAE integration efforts for NASA’s Aeronautics Research Mission Directorate at NASA Headquarters in Washington.
      By using this form of digital engineering, NASA’s aeronautical innovators can have a better idea of how their research in one area (say, ultra-efficient airliners) could best benefit, and work in tandem, with another area (say, future airspace safety).
      Using detailed, customizable digital models, researchers can simulate these complex systems working together with a high degree of accuracy and then figure out how the greatest benefits could be achieved.
      “As we move toward these advanced systems, MBSAE can connect different disciplines and determine how to eke out the best performance,” Hendricks said.
      That process feeds back into the research itself, helping researchers to significantly improve aviation’s sustainability – amongst other goals.
      Zeroing In
      MBSAE does more than integrating complex systems, however. Each system, individually, can be optimized using MBSAE tools.
      “Before the technology is even fully developed, we can run highly accurate digital simulations that inform the research itself,” Hendricks said. “A digital flight test is a lot simpler and less costly than a real flight test.”
      For example, one of NASA’s new MBSAE tools, Aviary, includes the ability to consider gradients. That means Aviary can figure out how to more efficiently optimize a given technology.
      Say a researcher would like to know which type of battery is needed to power an airplane during a certain maneuver. The researcher inputs information about the airplane, the maneuver, and battery technologies into Aviary, then Aviary goes and runs digital flight tests and comes back with which type of battery worked best.
      Digital flights tests like this can be done for myriad other areas as well, ranging from an aircraft’s overall shape to the size of its engine core, its electrical systems, and beyond. Then, the digital flight tests can help figure out how to combine these systems in the most effective way.
      Digital Era Aeronautics
      Another way MBSAE can come in handy is the scale of these aviation transformations.
      With demand for single-aisle airliners expected to rise dramatically in the coming decades, measuring the emissions reductions from a certain wing design, for example, would not just extend to one aircraft, but also an entire fleet.
      “We’ll be able to take what we learn from our sustainable aviation projects and simulate the technology entering the fleet at certain points,” said Rich Wahls, NASA’s mission integration manager for the Sustainable Flight National Partnership at NASA Headquarters. “We can model the fleet itself to see how much more sustainable these technologies are across the board.”
      Ultimately, MBSAE also represents a new era in aeronautical innovation – both at NASA and in the aviation industry, with whom NASA is working closely to ensure its MBSAE efforts are cross compatible on an opensource platform.
      “The MBSAE team has lots of early-to-mid career folks,” Hendricks said. “It’s great to see the younger generation get involved and even take the lead, especially since these digital efforts can facilitate knowledge transfer as well.”
      About the Author
      John Gould
      Aeronautics Research Mission DirectorateJohn Gould is a member of NASA Aeronautics' Strategic Communications team at NASA Headquarters in Washington, DC. He is dedicated to public service and NASA’s leading role in scientific exploration. Prior to working for NASA Aeronautics, he was a spaceflight historian and writer, having a lifelong passion for space and aviation.
      Facebook logo @NASA@NASAaero@NASA_es @NASA@NASAaero@NASA_es Instagram logo @NASA@NASAaero@NASA_es Linkedin logo @NASA Explore More
      2 min read System-Wide Safety Project Description
      Article 4 days ago 1 min read System-Wide Safety Project Leadership
      Article 4 days ago 3 min read NASA Embraces Streaming Service to Reach, Inspire Artemis Generation
      Article 7 days ago Keep Exploring Discover More Topics From NASA
      Missions
      Artemis
      Aeronautics STEM
      Explore NASA’s History
      Share
      Details
      Last Updated Aug 04, 2024 EditorJim BankeContactJim Bankejim.banke@nasa.gov Related Terms
      Aeronautics Aeronautics Research Mission Directorate Flight Innovation Sustainable Flight National Partnership View the full article
    • By NASA
      The core stage is the backbone of the SLS (Space Launch System) rocket that will help power NASA’s Artemis II mission to send a crew of four astronauts around the Moon in 2025. Here, the core stage is currently behind scaffolding to allow work to continue at NASA’s Michoud Assembly Facility in New Orleans. The stage’s two massive propellant tanks hold a collective 733,000 gallons of liquid propellant to power the four RS-25 engines at its base. Following hardware acceptance reviews and final checkouts, the stage will be readied for delivery via the agency’s Pegasus barge to NASA’s Kennedy Space Center in Florida for Artemis II launch preparations. (NASA/ Eric Bordelon) NASA will roll the fully assembled core stage for the agency’s SLS (Space Launch System) rocket that will launch the first crewed Artemis mission out of NASA’s Michoud Assembly Facility in New Orleans in mid-July. The 212-foot-tall stage will be loaded on the agency’s Pegasus barge for delivery to Kennedy Space Center in Florida.
      Media will have the opportunity to capture images and video, hear remarks from agency and industry leadership, and speak to subject matter experts with NASA and its Artemis industry partners as crews move the rocket stage to the Pegasus barge.
      NASA will provide additional information on specific timing later, along with interview opportunities. This event is open to U.S. and international media. International media must apply by June 14. U.S. media must apply by July 3. The agency’s media credentialing policy is available online.  
      Interested media must contact Corinne Beckinger at corinne.m.beckinger@nasa.gov and Craig Betbeze at craig.c.betbeze@nasa.gov. Registered media will receive a confirmation by email.
      The rocket stage with its four RS-25 engines will provide more than 2 million pounds of thrust to send astronauts aboard the Orion spacecraft for the Artemis II mission. Once at Kennedy, teams with NASA’s Exploration Ground Systems Program will finish outfitting the stage and prepare it for stacking and launch. Artemis II is currently scheduled for launch in September 2025.
      Building, assembling, and transporting the core stage is a collaborative process for NASA, Boeing, the core stage lead contractor, and lead RS-25 engines contractor Aerojet Rocketdyne, an L3 Harris Technologies company.
      NASA is working to land the first woman, first person of color, and its first international partner astronaut on the Moon under the agency’s Artemis campaign. The SLS rocket is part of NASA’s backbone for deep space exploration, along with the Orion spacecraft, supporting ground systems, advanced spacesuits and rovers, the Gateway in orbit around the Moon, and commercial human landing systems. The SLS rocket is the only rocket designed to send Orion, astronauts, and supplies to the Moon in a single launch.
      Learn more about NASA’s Artemis campaign:
      https://www.nasa.gov/artemis/
      -end- 
      Rachel Kraft
      NASA Headquarters, Washington
      202-358-1100
      rachel.h.kraft@nasa.gov
      Corinne Beckinger 
      Marshall Space Flight Center, Huntsville, Ala. 
      256-544-0034
      corinne.m.beckinger@nasa.gov 
      View the full article
    • By NASA
      NASA will roll the fully assembled core stage for the agency’s SLS (Space Launch System) rocket that will launch the first crewed Artemis mission out of NASA’s Michoud Assembly Facility in New Orleans in mid-July. The 212-foot-tall stage will be loaded on the agency’s Pegasus barge for delivery to Kennedy Space Center in Florida.
      Media will have the opportunity to capture images and video, hear remarks from agency and industry leadership, and speak to subject matter experts with NASA and its Artemis industry partners as crews move the rocket stage to the Pegasus barge.
      The core stage is the backbone of the SLS (Space Launch System) rocket that will help power NASA’s Artemis II mission to send a crew of four astronauts around the Moon in 2025. Here, the core stage is currently behind scaffolding to allow work to continue at NASA’s Michoud Assembly Facility in New Orleans. The stage’s two massive propellant tanks hold a collective 733,000 gallons of liquid propellant to power the four RS-25 engines at its base. Following hardware acceptance reviews and final checkouts, the stage will be readied for delivery via the agency’s Pegasus barge to NASA’s Kennedy Space Center in Florida for Artemis II launch preparations. NASA will provide additional information on specific timing later, along with interview opportunities. This event is open to U.S. and international media. International media must apply by June 14. U.S. media must apply by July 3. The agency’s media credentialing policy is available online.  
      Interested media must contact Corinne Beckinger at corinne.m.beckinger@nasa.gov and Craig Betbeze at craig.c.betbeze@nasa.gov. Registered media will receive a confirmation by email.
      The rocket stage with its four RS-25 engines will provide more than 2 million pounds of thrust to send astronauts aboard the Orion spacecraft for the Artemis II mission. Once at Kennedy, teams with NASA’s Exploration Ground Systems Program will finish outfitting the stage and prepare it for stacking and launch. Artemis II is currently scheduled for launch in September 2025.
      Building, assembling, and transporting the core stage is a collaborative process for NASA, Boeing, the core stage lead contractor, and lead RS-25 engines contractor Aerojet Rocketdyne, an L3 Harris Technologies company.
      NASA is working to land the first woman, first person of color, and its first international partner astronaut on the Moon under the agency’s Artemis campaign. The SLS rocket is part of NASA’s backbone for deep space exploration, along with the Orion spacecraft, supporting ground systems, advanced spacesuits and rovers, the Gateway in orbit around the Moon, and commercial human landing systems. The SLS rocket is the only rocket designed to send Orion, astronauts, and supplies to the Moon in a single launch.
      Learn more about NASA’s Artemis campaign:
      News Media Contact
      Rachel Kraft
      NASA Headquarters, Washington
      202-358-1100
      rachel.h.kraft@nasa.gov
      Corinne Beckinger
      Marshall Space Flight Center, Huntsville, Ala.
      256-544-0034
      corinne.m.beckinger@nasa.gov
      View the full article
    • By NASA
      Operational modal analysis (OMA) techniques have been used to identify the modal characteristics of the Artemis I launch vehicle during the Dynamic Rollout Test (DRT) and Wet Dress Rehearsal (WDR) configuration prior to launch. Forces induced during rollout and on the launch pad are not directly measurable, thus necessitating a unique approach.

      NASA is developing the SLS to support lunar and deep space exploration. SLS is integrated inside the Vehicle Assembly Building (VAB) on the mobile launcher (ML), which supports the integrated SLS launch vehicle during transport to the pad through lift-off. The ML also provides the fuel, power, and data umbilicals running to the SLS and Orion Multi-Purpose Crew Vehicle (MPCV), as well as crew access to the MPCV crew module. The ML weighs ~10.6 million pounds and is over 380 feet tall. In the spring of 2022, the SLS was transported on the ML from the VAB to Launch Pad 39B (Figure 1) using the NASA crawler transporter (CT) to make this 4.2 mile trek, which takes ~8 hours. The CT alone weighs ~6.3 million pounds.
      Figure 1. Artemis I Rollout to Launch Pad 39B. Although the rollout environment produces relatively small launch vehicle structural loads in comparison to launch and ascent loads for most structures, the induced loads are fully representative of all loading across the entire vehicle, which is not feasible to replicate using localized shakers as was done in the Integrated Modal Test. As mentioned, forces induced during rollout and on the launch pad are not directly measurable, and OMA techniques were used to identify the modal characteristics of Artemis I in the DRT and WDR configurations. WDR, which typically includes vehicle fueling and other operations to demonstrate launch readiness, included several days of on-pad operations. Data collected for the WDR configuration, with partially filled core fuel tanks and without the CT under the ML, provided engineers another model configuration to check (Figure 2).
      Figure 2. Artemis I at Launch Pad 39B. Acquisition and processing the data from over 300 accelerometers located on Artemis I, ML, and CT was accomplished by a cross-program team of engineers and technicians from across the Agency, including from SLS, Exploration Ground Systems, and the NESC. Using analytical techniques developed from previous rollout tests combined with new data-processing methodologies, the team processed data from preselected CT speed increments during rollout and on-pad during WDR. By making the necessary modifications to the integrated models to match both the DRT and WDR configurations, the team was able to use those results to help make sense of what was being seen in the test data. This proved to be required for OMA testing on this structure, given the type of complex excitation that was being observed.

      For information, contact Dexter Johnson dexter.johnson@nasa.gov and Teresa Kinney teresa.l.kinney@nasa.gov.
      View the full article
    • By NASA
      4 min read
      Preparations for Next Moonwalk Simulations Underway (and Underwater)
      This staged scene and illustration represents what you might see when NASA’s University Innovation project awards teams of students with funds to conduct real-world aeronautical research that will help the agency transform aviation for the 21st century. NASA /Lillian Gipson / Getty Images NASA has selected another five university teams to participate in real-world aviation research challenges that could help transform flight in the skies above our communities.
      Research topics range from safeguarding automated aircraft from cyberattacks to finding ways to help aircraft operations across the nation more quickly recover from delays due to major storms or technical problems.
      “The idea is to give students, faculty and their partners the chance to conduct research – both physical and digital – that helps us realize our vision for 21st century aviation that is sustainable and offers more diverse air travel options,” said Koushik Datta, University Innovation project manager for NASA’s Aeronautics Research Mission Directorate.
      The University Innovation project includes two efforts through which universities are invited to submit research proposals and from which teams are then selected: the University Leadership Initiative (ULI) and the University Student Research Challenge (USRC).
      A key ULI goal is for faculty-led student teams to gain experience by participating in aeronautics research on a multidisciplinary team made up of partners from other universities and industry, including faculty and student populations who are underrepresented or have not applied their skills to aviation problems.
      Meanwhile, in addition to conducting technical research, student-led USRC teams help them develop skills in entrepreneurship and public communication. Each team of students selected receives a USRC grant from NASA – and the additional challenge of raising funds from the public through student-led crowdfunding.
      ULI makes selections once a year, while USRC manages multiple selection cycles each year, with proposals for the next selection cycle due by 5 p.m. EDT on March 21. Visit the NASA Aeronautics Solicitations page for more information.
      For ULI, three teams were selected resulting in a total of $18 million in awards during the next three years. For each team, the proposing university will serve as lead. The new ULI selections are:
      University of California, Berkeley
      The team will test ideas for improving the ability of the National Airspace System to become more resilient to reduce the disruptive impact major storms, facility outages, and other technical issues can have on airline flight operations. Team members include University of Maryland, University of Michigan, Morgan State University, University of Pennsylvania, Elizabeth City State University, United Airlines, Patty Clark Aviation Advisors, ATAC Corporation, Mead and Hunt, American Airlines, Vaughan College of Aeronautics and Technology, The Federal Aviation Administration, Lansing Community College, Community College of Philadelphia, and City College of San Francisco.
      Ohio University
      The team will seek to solve technical challenges associated with the ability of large drones to safely taxi, take off, and land at airports using automated navigation systems. Team members include Illinois Institute of Technology, Virginia Polytechnic Institute and State University, Tufts University, Stanford University, Veth Research Associates LLC, Reliable Robotics Corporation, Boeing, and Virginia Tech Transportation Institute.
      The George Washington University
      The team will investigate measures that can be taken to safeguard autonomous aircraft flying in high-density urban airspace from cyberattacks that could disrupt safe operations. Team members include Vanderbilt University, Purdue University, Tennessee State University, University of California, Irvine, The University of Texas at Austin, Collins Aerospace, Northern Virginia Community College, Cyber Security and Privacy Research Institute at The George Washington University, Skygrid (a Boeing Company), and the Secure Resilient Systems and Technology Group at MIT Lincoln Laboratory.
      For USRC, NASA selected two new university student teams to participate in this cycle with a USRC grant that can be up to $80,000. The new USRC selections are:
      Cornell University
      The team’s project is titled “Learning Cooperative Policies for Adaptive Human-Drone Teaming in Shared Airspace” and will work to enable new coordination and communication models for smoother, more efficient and robust air traffic flow. The student team members are: Mehrnaz Sabet (lead), Aaron Babu, Marcus Lee, Joshua Park, Francis Pham, Owen Sorber, Roopak Srinivasan, and Austin Zhao. Faculty mentors are Sanjiban Choudhury and Susan Fussell.
      University of Washington, Seattle
      The team’s project is titled “Investigation on Cryogenic Fluid Chill-Down Time for Supersonic Transport Usage” and will investigate using vortex generators to reduce the  boil-off of cryogenic fluids in pipes. Student team members are Ryan Fidelis (lead), Alexander Ala, and Robert Breidenthal. The faculty mentor is Fiona Spencer.
      About the Author
      Jim Banke
      Managing Editor/Senior WriterJim Banke is a veteran aviation and aerospace communicator with more than 35 years of experience as a writer, producer, consultant, and project manager based at Cape Canaveral, Florida. He is part of NASA Aeronautics' Strategic Communications Team and is Managing Editor for the Aeronautics topic on the NASA website.
      Facebook logo @NASA@NASAaero@NASA_es @NASA@NASAaero@NASA_es Instagram logo @NASA@NASAaero@NASA_es Linkedin logo @NASA Explore More
      3 min read NASA Collaborates in an International Air Quality Study
      Article 1 week ago 2 min read NASA Releases STEM Toolkit for Advanced Air Mobility
      Article 3 weeks ago 4 min read NASA Autonomous Flight Software Successfully Used in Air Taxi Stand-Ins
      Article 4 weeks ago Keep Exploring Discover More Topics From NASA
      Aeronautics STEM
      Black History Month
      NASA History
      Aeronautics Research Mission Directorate
      Share
      Details
      Last Updated Feb 21, 2024 EditorJim BankeContactJim Bankejim.banke@nasa.gov Related Terms
      Aeronautics Aeronautics Research Mission Directorate Flight Innovation Transformative Aeronautics Concepts Program University Innovation University Leadership Initiative University Student Research Challenge View the full article
  • Check out these Videos

×
×
  • Create New...