Boeing X-48

Last updated

X-48
X-48B from above.jpg
X-48B
RoleExperimental unmanned aerial vehicle
Manufacturer Boeing
First flightJuly 20, 2007
StatusRetired [1]
Produced2

The Boeing X-48 is an American experimental unmanned aerial vehicle (UAV) built to investigate the characteristics of blended wing body (BWB) aircraft. Boeing designed the X-48 and two examples were built by Cranfield Aerospace in the UK. Boeing began flight testing the X-48B version for NASA in 2007. The X-48B was later modified into the X-48C version, which was flight tested from August 2012 to April 2013. Boeing and NASA plan to develop a larger BWB demonstrator.

Contents

Design and development

Background

Boeing had in the past studied a blended wing body design, but found that passengers did not like the theater-like configuration of the mock-up; the design was dropped for passenger airliners, but retained for military aircraft such as aerial refueling tankers. [N 1] [2]

McDonnell Douglas developed the blended wing concept in the late 1990s, [3] and Boeing presented it during an annual Joint AIAA/ASME/SAE/ASEA Propulsion Conference in 2004. [4] The McDonnell Douglas engineers believed their design had several advantages, but their concept, code named "Project Redwood", found little favor at Boeing after their 1997 merger. [5] [6] The most difficult problem they solved was that of ensuring passengers a safe and fast escape in case of an accident, since emergency door locations were completely different from those in a conventional aircraft. [7]

The blended wing body (BWB) concept offers advantages in structural, aerodynamic and operating efficiencies over today's more conventional fuselage-and-wing designs. These features translate into greater range, fuel economy, reliability and life cycle savings, as well as lower manufacturing costs. They also allow for a wide variety of potential military and commercial applications. [8] [9]

X-48

X-48B on static display at the 2006 Edwards Airshow Edw-2006-X48-061028-01-8.jpg
X-48B on static display at the 2006 Edwards Airshow

Boeing Phantom Works developed the blended wing body (BWB) aircraft concept in cooperation with the NASA Langley Research Center. In an initial effort to study the flight characteristics of the BWB design, a remote-controlled propeller-driven blended wing body model with a 17 ft (5.2 m) wingspan was flown in 1997. The next step was to fly the 35 ft (10.7 m) wide X-48A in 2004, but the program was canceled before manufacturing. [10]

Research at Phantom Works then focused on a new model, designated X-48B, two examples were built by United Kingdom-based Cranfield Aerospace, a division of Cranfield University. Norman Princen, Boeing's chief engineer for the project, stated in 2006: "Earlier wind-tunnel testing and the upcoming flight testing are focused on learning more about the BWB's low-speed flight-control characteristics, especially during takeoffs and landings. Knowing how accurately our models predict these characteristics is an important step in the further development of this concept." [11]

The X-48B has a 21-foot (6.4 m) wingspan, weighs 392 pounds (178 kg), and is built from composite materials. It is powered by three small turbojet engines and is expected to fly at up to 120 kn (220 km/h) and reach an altitude of 10,000 feet (3,000 m). [11] [12] The X-48B is an 8.5% scaled version of a conceptual 240 feet (73 m) span design. [12] [13] Though passenger versions of the X-48B have been proposed, the design has a higher probability of first being used for a military transport. [13]

The X-48C featuring two engines and inboard vertical stabilizers NASA-Boeing X-48C before first flight (cropped).jpg
The X-48C featuring two engines and inboard vertical stabilizers

Wind tunnel testing on a 12 feet (3.7 m) wide blended wing body model was completed in September 2005. [14] [15] During April and May 2006, NASA performed wind tunnel tests on X-48B Ship 1 at a facility shared by Langley and Old Dominion University. [15] [16] After the wind tunnel testing, the vehicle was shipped to NASA's Dryden Flight Research Center at Edwards Air Force Base to serve as a backup to X-48B Ship 2 for flight testing. [17] X-48B Ship 2 then conducted ground tests and taxi testing in preparation for flight. [18] In November 2006, ground testing began at Dryden, to validate the aircraft's systems integrity, telemetry and communications links, flight-control software and taxi and takeoff characteristics.

The second X-48B was modified into the X-48C starting in 2010 for further flight tests. [19] The X-48C has its vertical stabilizers moved inboard on either side of the engines, and its fuselage extended aft, both to reduce the aircraft's noise profile; it was to be powered by two JetCat turbines, each producing 80 pounds-force (360 N) of thrust. [20] [21] The X-48C was instead modified to use two Advanced Micro Turbo (AMT) turbojet engines in 2012. [22]

Following flight testing of the X-48C in April 2013, Boeing and NASA announced future plans to develop a larger BWB demonstrator capable of transonic flight. [23]

Operational history

X-48B on its first flight First X-48B flight.jpg
X-48B on its first flight
X-48B at first flight as seen from below X-48B seen from left down.jpg
X-48B at first flight as seen from below

The X-48B first flew on July 20, 2007, reaching an altitude of 7,500 ft (2,286 m); the flight lasting 31 minutes. [17] [18] [24] The remotely piloted aircraft was successfully stalled for the first time on September 4, 2008, with fixed leading edge slats, a forward center of gravity, and 23-degree angle of attack (2° beyond the maximum coefficient of lift). Stall testing was repeated on September 11 with a NASA pilot at the console. [25]

On March 19, 2010, NASA and Boeing successfully completed the initial flight testing phase of the X-48B. [26] Fay Collier, manager of the ERA Project in NASA's Aeronautics Research Mission Directorate commented on the completion of the first phase of testing saying, "This project is a huge success. Bottom line: the team has proven the ability to fly tailless aircraft to the edge of the low-speed envelope safely." [27]

Following the installation of a new flight computer in 2010, the X-48B was to continue a new phase of flight tests to investigate controllability aspects. [28] [29] The second phase of flight tests with the X-48B began in September 2010. [30]

The X-48C first flew on August 7, 2012. [31] Engine yaw control was among the aspects to be studied. [32] The X-48C completed its 8-month flight test program with its 30th flight on 9 April 2013. [33]

Variants

X-48A
The initial planned 35 ft (10.7 m) wide version. It was canceled before manufacture.
X-48B
Two 8.5% scale aircraft that have been used for flight testing.
X-48C
A modified, two-engine version of the X-48B intended to test a low-noise design. [34]

Specifications (X-48B)

A three percent scale model of the X-48C in NASA Langley's 12 ft (3.7 m) Low-Speed Tunnel X-48C Prototype.jpg
A three percent scale model of the X-48C in NASA Langley's 12 ft (3.7 m) Low-Speed Tunnel

Data from Designation-systems.net, [35] NASA [36]

General characteristics

Performance

See also

Aircraft of comparable role, configuration, and era

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References

Notes

  1. Quote: Boeing once toyed with a blended wing-body, a sort of flying wing, to produce significantly better aerodynamics and fuel efficiency. Passengers would have sat in a wide cabin, rather like a small amphitheater. But tests with a mock-up produced such a negative reaction that the company dropped the technology, except for military refueling aircraft. [2]

Citations

  1. "X-48 Research: All good things must come to an end". NASA. April 17, 2013.
  2. 1 2 "Aircraft emissions". The Economist, June 8, 2006. Retrieved: August 12, 2012.
  3. Liebeck 2004, p. 10.
  4. Liebeck 2004, p. 18.
  5. Norris and Wagner 2009, p. 18.
  6. Boeing Chronology, 1997–2001; Archived January 2, 2013, at the Wayback Machine . Boeing.
  7. Liebeck 2004, p. 24.
  8. "Boeing to Begin Ground Testing of X-48B Blended Wing Body Concept". Archived August 19, 2012, at the Wayback Machine . Boeing, October 27, 2006. Retrieved: April 10, 2012.
  9. Lorenz, Phillip III. "AEDC testing brings unique blended wing aircraft closer to flight". Archived July 14, 2014, at the Wayback Machine . AEDC, U.S. Air Force, July 3, 2007. Retrieved April 10, 2012.
  10. Parsch, Andreas. "Boeing X-48." designation-systems.net, November 24, 2009.
  11. 1 2 Koehler, Tom. "Boeing to Begin Ground Testing of X-48B Blended Wing Body Concept." Archived August 19, 2012, at the Wayback Machine Boeing, October 27, 2006. Retrieved: October 24, 2010.
  12. 1 2 Warwick, Graham. "British blend: UAV X-planes help Boeing with blended wing concept." Flight International, May 30, 2006.
  13. 1 2 Jacobs, Karrie. "Thinking Outside the Tube." Wired, February 2007. Retrieved: April 11, 2007.
  14. Coppinger, Rob. "X-48B scale model to fly next year." Flight International, November 22, 2005. Retrieved: April 11, 2007.
  15. 1 2 Morris, Jefferson. "Blended Wing Body Prototype Wrapping Up Wind Tunnel Tests." [ permanent dead link ]AviationWeek.com, May 8, 2006.
  16. Barnstorff, Kathy. "The X-48B Blended Wing Body." Archived January 15, 2011, at the Wayback Machine NASA Langley Research Center, May 4, 2006. Retrieved: April 11, 2007.
  17. 1 2 Koehler, Tom and Daryl Stephenson. "Boeing Flies Blended Wind Body Research Aircraft." Boeing, July 26, 2007.
  18. 1 2 Creech, Gray. "X-48B Blended Wing Body Research Aircraft Takes First Flight." Archived May 30, 2008, at the Wayback Machine NASA, July 26, 2007. Retrieved: July 26, 2007.
  19. "Second X-48B Modified Into X-48C Configuration" Archived July 9, 2017, at the Wayback Machine . NASA Dryden Flight Research Center, February 11, 2010.
  20. "NASA Demonstrates Controllability of X-48B". Aviation Week & Space Technology, Vol. 172, No. 14, April 12, 2010, p. 19.
  21. Mecham, Michael. "New Tests Pending For X-48 Flying Wing." [ permanent dead link ]Aviation Week & Space Technology, September 10, 2010.
  22. Norris, Guy. "New Flight Trials For X-51, X-48, Phantom Eye." Archived May 17, 2013, at the Wayback Machine Aviation Week, July 2, 2012.
  23. "Boeing's X-48C completes flight tests.". UPI
  24. Creech, Gray. "Skyray 48 Takes Flight." Archived March 31, 2017, at the Wayback Machine NASA, September 11, 2007. Retrieved: July 25, 2011.
  25. "Stall Success". Aviation Week & Space Technology , Vol. 169, No. 10, September 15, 2008, p. 20.
  26. Paur, Jason. "NASA's Mini X-Plane Completes Initial Flight Testing." Wired News, Autopia, April 6, 2010.
  27. Creech, Gray. "X-48B BWB Team Completes Phase 1 Test Flights." NASA , April 6, 2010.
  28. Cohen, Aubrey. "NASA-Boeing team done first flight phase of blended wing body plane." Seattlepi.com, April 6, 2010.
  29. Croft, Jon. "NASA, Boeing complete X-48B flight test campaign." Flight International, April 6, 2010.
  30. Creech, Gray. "Back in the Air: X-48B Resumes Flight Tests at NASA Dryden" Archived July 9, 2017, at the Wayback Machine . NASA Dryden Flight Research Center, September 21, 2010.
  31. Terdiman, Daniel. "NASA's futuristic X-48C hybrid wing-body plane takes flight" cnet.com, August 7, 2012.
  32. "NASA And Boeing Fly Their Prototype X-48C For The First Time". NASA , August 7, 2012. Retrieved: August 12, 2012.
  33. "Boeing X-48C Blended Wing Body Research Aircraft Completes Flight Testing." Boeing
  34. Norris, Guy. "First Boeing X-48C Flight Imminent, NASA Says." Archived January 10, 2014, at the Wayback Machine Aviation Week, August 2, 2012. Retrieved: August 3, 2012.
  35. Parsch, Andreas. "Boeing X-48." Designation-Systems.net, June 2009. Retrieved: April 7, 2010.
  36. "X-48B Blended Wing Body." NASA, February 11, 2010. Retrieved: April 7, 2010.

Bibliography

External images
Searchtool.svg X-48B image
Searchtool.svg X-48C during construction
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