Bell Boeing Quad TiltRotor

Last updated
Quad TiltRotor
Quad TiltRotor rendering.jpg
Quad Tiltrotor art concept
Role Cargo tiltrotor
Manufacturer Bell and Boeing
StatusStudy
Developed from Bell Boeing V-22 Osprey

The Bell Boeing Quad TiltRotor (QTR) is a proposed four-rotor derivative of the Bell Boeing V-22 Osprey developed jointly by Bell Helicopter and Boeing. The concept is a contender in the U.S. Army's Joint Heavy Lift program (a part of Future Vertical Lift program). It would have a cargo capacity roughly equivalent to the C-130 Hercules, cruise at 250 knots, and land at unimproved sites vertically like a helicopter. [1]

Contents

Development

Background

Bell developed its model D-322 as a quad tiltrotor concept in 1979. The Bell Boeing team disclosed a Quad TiltRotor design in 1999 which the companies had been investigating during the previous two years. The design was for a C-130-size V/STOL transport for the US Army's Future Transport Rotorcraft program and would have 50% commonality with the V-22. This design was to have a maximum takeoff weight of 100,000 lb (45,000 kg) with a payload of up to 25,000 lb (11,000 kg) in a hover. [2] [3] The design was downsized to be more V-22-based and to have a payload of 18,000 to 20,000 lb (8,200 to 9,100 kg). This version was referred to as "V-44". [2] [4] Bell received contracts to study related technologies in 2000. Development was not pursued by the US Department of Defense. [2]

From 2000 to 2006, studies of the aerodynamics and performance of a Quad Tilt Rotor were conducted at the University of Maryland, College Park. This effort was initially funded by NASA/AFDD and subsequently by Bell. An experimental investigation in helicopter mode with ground effect found that it was possible to reduce the download on the aircraft from 10% of the total thrust to an upload of 10% of the thrust. [5] A parallel Computational Fluid Dynamics (CFD) study confirmed these findings. [6]

Joint Heavy Lift studies

In September 2005, Bell and Boeing received a cost-sharing contract worth US$3.45 million from the U.S. Army's Aviation Applied Technology Directorate for an 18-month conceptual design and analysis study lasting through March 2007, in conjunction with the Joint Heavy Lift program. [7] [8] The contract was awarded to Bell Helicopter, which is teaming with Boeing's Phantom Works. The QTR study is one of five designs; one of the five is also a Boeing program, an advanced version of the CH-47 Chinook. [1]

During the initial baseline design study, Bell's engineers were designing the wing, engine and rotor, while the Boeing team was designing the fuselage and internal systems. [9] A similar arrangement is used on the V-22.

A one-fifth-scale wind tunnel model has undergone testing in the Transonic Dynamics Tunnel (a unique transonic wind tunnel) at NASA's Langley Research Center during summer 2006. The "semi-span" model (representing the starboard half of the aircraft) measured 213 inches in length and had powered 91-inch rotors, operational nacelles, and "dynamically representative" wings. [10]

The primary test objective was to study the aeroelastic effects on the aft wing of the forward wing's rotors and establish a baseline aircraft configuration. [1] Alan Ewing, Bell's QTR program manager, reported that "Testing showed those loads from that vortex on the rear rotor [are the] same as the loads we see on the front [rotors]," and "Aeroelastic stability of the wing looks exactly the same as the conventional tiltrotor". These tests used a model with a three-bladed rotor, future tests will explore the effects of using a four-bladed system. [9]

Besides the research performed jointly under the contract, Bell has funded additional research and wind tunnel testing in cooperation with NASA and the Army. [11] After submission of initial concept study reports, testing of full-scale components and possibly a sub-scale vehicle test program was expected to begin. [1] Pending approval, first flight of a full-scale prototype aircraft was slated for 2012. [9]

The study was completed in May 2007, [12] with the Quad TiltRotor selected for further development. However, additional armor on Future Combat Systems manned ground vehicles caused their weight to increase from 20 tons to 27 tons, requiring a larger aircraft. [13] In mid-2008, the U.S. Army continued the Joint Heavy Lift (JHL) studies with new contracts to the Bell-Boeing and Karem Aircraft/Lockheed Martin teams. The teams were to modify their designs to reach new JHL specifications. JHL became part of the new US Air Force/Army Joint Future Theater Lift (JFTL) program in 2008. [14] In mid-2010, the US DoD was formulating a vertical lift aircraft plan with JFTL as a part. [15] The DoD also requested information from the aerospace industry on technologies for JFTL in October 2010. [16] [17] [ needs update ]

Design

The conceptual design featured a large tandem wing aircraft with V-22 type engines and 50-foot (15 m) rotors at each of the four wing tips. The C-130-size fuselage would have a 747-inch (19.0 m) cargo bay with a rear loading ramp that could carry 110 paratroopers or 150 standard-seating passengers. In cargo configuration, it would accommodate eight 463L pallets. This baseline version includes a fully retractable refueling probe and an interconnecting drive system for power redundancy. [9]

In addition, the Bell-Boeing team included eight possible variants, or "excursion designs", including a sea-based variant. The design team planned on payloads ranging from 16 to 26 tons and a range of 420 to 1,000 nautical miles (780 to 1,850 km). [9] One of the design excursions explored, dubbed the "Big Boy", would have 55-foot (17 m) rotors and an 815-inch (20.7 m) cargo bay, making it able to carry one additional 463L pallet and accommodate a Stryker armored combat vehicle. [9]

See also

Related development

Aircraft of comparable role, configuration, and era

Related lists

Related Research Articles

<span class="mw-page-title-main">VTOL</span> Aircraft takeoff and landing done vertically

A vertical take-off and landing (VTOL) aircraft is one that can take off and land vertically without relying on a runway. This classification can include a variety of types of aircraft including helicopters as well as thrust-vectoring fixed-wing aircraft and other hybrid aircraft with powered rotors such as cyclogyros/cyclocopters and gyrodynes.

<span class="mw-page-title-main">Bell Boeing V-22 Osprey</span> Military transport tiltrotor

The Bell Boeing V-22 Osprey is an American multi-mission, tiltrotor military aircraft with both vertical takeoff and landing (VTOL) and short takeoff and landing (STOL) capabilities. It is designed to combine the functionality of a conventional helicopter with the long-range, high-speed cruise performance of a turboprop aircraft. The V-22 is operated by the United States and Japan, and is not only a new aircraft design, but a new type of aircraft that entered service in the 2000s, a tiltrotor compared to fixed wing and helicopter designs. The V-22 first flew in 1988 and after a long development was fielded in 2007. The design essentially combines the vertical takeoff ability of a helicopter, but the range of a fixed-wing airplane.

<span class="mw-page-title-main">Tiltrotor</span> Aircraft type

A tiltrotor is an aircraft that generates lift and propulsion by way of one or more powered rotors mounted on rotating shafts or nacelles usually at the ends of a fixed wing. Almost all tiltrotors use a transverse rotor design, with a few exceptions that use other multirotor layouts.

<span class="mw-page-title-main">Bell XV-15</span> American experimental tiltrotor aircraft

The Bell XV-15 is an American tiltrotor VTOL aircraft. It was the second successful experimental tiltrotor aircraft and the first to demonstrate the concept's high speed performance relative to conventional helicopters.

<span class="mw-page-title-main">Leonardo AW609</span> Twin-engine tiltrotor VTOL aircraft

The Leonardo AW609, formerly the AgustaWestland AW609, and originally the Bell/Agusta BA609, is a twin-engined tiltrotor VTOL aircraft with an overall configuration similar to that of the Bell Boeing V-22 Osprey. It is capable of landing vertically like a helicopter while having a range and speed in excess of conventional rotorcraft. The AW609 is aimed at the civil aviation market, in particular VIP customers and offshore oil and gas operators. It has progressed from a concept in the late 1990s, to development and testing, and is working towards certification in the 2020s.

<span class="mw-page-title-main">Piasecki X-49 SpeedHawk</span> Type of aircraft

The Piasecki X-49 "SpeedHawk" is an American four-bladed, twin-engined experimental high-speed compound helicopter developed by Piasecki Aircraft. The X-49A is based on the airframe of a Sikorsky YSH-60F Seahawk, but utilizes Piasecki's proprietary vectored thrust ducted propeller (VTDP) design and includes the addition of lifting wings. The concept of the experimental program was to apply the VTDP technology to a production military helicopter to determine any benefit gained through increases in performance or useful load.

<span class="mw-page-title-main">Tandem-rotor aircraft</span> Helicopter with two horizontal rotor assemblies

A tandem-rotor aircraft is an aircraft with two large helicopter rotor assemblies mounted one in front of the other in the horizontal plane.

<span class="mw-page-title-main">Bell XV-3</span> Experimental tiltrotor aircraft to explore convertiplane technologies

The Bell XV-3 is an American tiltrotor aircraft developed by Bell Helicopter for a joint research program between the United States Air Force and the United States Army in order to explore convertiplane technologies. The XV-3 featured an engine mounted in the fuselage with driveshafts transferring power to two-bladed rotor assemblies mounted on the wingtips. The wingtip rotor assemblies were mounted to tilt 90 degrees from vertical to horizontal, designed to allow the XV-3 to take off and land like a helicopter but fly at faster airspeeds, similar to a conventional fixed-wing aircraft.

A convertiplane is defined by the Fédération Aéronautique Internationale as an aircraft which uses rotor power for vertical takeoff and landing (VTOL) and converts to fixed-wing lift in normal flight. In the US it is further classified as a sub-type of powered lift. In popular usage it sometimes includes any aircraft that converts in flight to change its method of obtaining lift.

<span class="mw-page-title-main">Bell 533</span> Research helicopter built by Bell Helicopter

The Bell 533 was a research helicopter built by Bell Helicopter under contract with the United States Army during the 1960s, to explore the limits and conditions experienced by helicopter rotors at high airspeeds. The helicopter was a YH-40—a preproduction version of the UH-1 Iroquois—modified and tested in several helicopter and compound helicopter configurations. The Bell 533 was referred to as the High Performance Helicopter (HPH) by the Army, and reached a top speed of 274.6 knots in 1969, before being retired.

Bell Agusta Aerospace Company (BAAC) was a joint venture formed in 1998 by Bell Helicopter and Agusta, who collaborated on a variety of products dating back to 1952. The joint venture was dissolved in 2011, when AgustaWestland took full ownership of the project, renaming it as the AgustaWestland Tilt-Rotor Company (AWTRC).

<span class="mw-page-title-main">Powered lift</span> VTOL capable fixed-wing aircraft

A powered lift aircraft takes off and lands vertically under engine power but uses a fixed wing for horizontal flight. Like helicopters, these aircraft do not need a long runway to take off and land, but they have a speed and performance similar to standard fixed-wing aircraft in combat or other situations.

Karem Aircraft, Inc. is an American aerospace manufacturer company with offices in Lake Forest, California; York, Virginia; and Victorville, California, founded in 2004 by Abraham Karem as a rapid development firm specializing in advanced tiltrotor transport aircraft. Karem was the former chief designer for the Israeli Air Force — who built his first drone during 1973's Yom Kippur War — and has been described by The Economist as the man who "created the robotic plane that transformed the way modern warfare is waged — and continues to pioneer other airborne innovations". He emigrated to the United States in the late 1970s.

<span class="mw-page-title-main">Baldwin Mono Tiltrotor</span> Type of aircraft

The Baldwin Mono Tiltrotor project is a research effort into a tiltrotor aircraft that uses only one rotor. Like other tiltrotor configurations, the mono tiltrotor combines the vertical lift capability and structural efficiency of a helicopter with the speed and range of a fixed-wing aircraft.

<span class="mw-page-title-main">Future Vertical Lift</span> Planned family of US military helicopters

Future Vertical Lift (FVL) is a plan to develop a family of military helicopters for the United States Armed Forces. Five different sizes of aircraft are to be developed, sharing common hardware such as sensors, avionics, engines, and countermeasures. The U.S. Army has been considering the program since 2004. FVL is meant to develop replacements for the Army's UH-60 Black Hawk, AH-64 Apache, CH-47 Chinook, and OH-58 Kiowa helicopters. The precursor for FVL is the Joint Multi-Role (JMR) helicopter program.

<span class="mw-page-title-main">Bell V-280 Valor</span> American tiltrotor VTOL aircraft

The Bell V-280 Valor is a tiltrotor aircraft being developed by Bell Helicopter for the United States Army's Future Vertical Lift (FVL) program. The aircraft was officially unveiled at the 2013 Army Aviation Association of America's (AAAA) Annual Professional Forum and Exposition in Fort Worth, Texas. The V-280 made its first flight on 18 December 2017 in Amarillo, Texas.

<span class="mw-page-title-main">Bell V-247 Vigilant</span> Unmanned military tiltrotor concept

The Bell V-247 Vigilant is a concept by Bell Helicopter to develop a large tiltrotor unmanned aerial vehicle.

The Future Attack Reconnaissance Aircraft (FARA) program was initiated by the United States Army in 2018 to develop a successor to the Bell OH-58 Kiowa scout helicopter as part of the Future Vertical Lift program. The OH-58 was retired in 2017; three prior programs for a successor were cancelled prior to reaching production: Light Helicopter Experimental, Armed Reconnaissance Helicopter, and Armed Aerial Scout. Several billions of dollars were spent without delivering any new helicopters to service, due to this cycle of development and cancellation. During this time the armed scout role was filled primarily by the Vietnam-era OH-58, which was finally retired in the late 2010s, leaving the Army to use attack helicopters to fill in this role.

European Future Advanced Rotorcraft (EuroFAR) was a proposed tiltrotor aircraft that was pursued during the 1980s and 1990s. It was a collaborative programme undertaken by the EuroFAR consortium, which comprised Aerospatiale, Agusta, Aeritalia, Messerschmitt-Bölkow-Blohm, Westland, and Construcciones Aeronáuticas SA (CASA).

References

  1. 1 2 3 4 "Diversity in Design: Boeing offers 2 of 5 development options in rotorcraft program" Archived 2022-12-10 at the Wayback Machine . Boeing Frontiers magazine, January 2007.
  2. 1 2 3 Norton 2004, p. 86.
  3. Hirschberg, Mike. "On the Vertical Horizon: Bell Designs Are Accelerating at Full Tilt". vtol.org.
  4. V-44: Pentagon's Next Air Transport Archived May 2, 2006, at the Wayback Machine . Popular Mechanics, September 2000.
  5. Radhakrishnan, Anand and Fredric Schmitz. "An Experimental Investigation of Ground Effect on a Quad Tilt Rotor in Hover and Low Speed Forward Flight". University of Maryland, 2006.
  6. Gupta, Vinit. "Quad Tilt Rotor Simulations in Helicopter Mode using Computational Fluid Dynamics" Archived 2012-03-25 at the Wayback Machine . University of Maryland, 2005.
  7. "Boeing receives two study contracts from U.S. Army for Joint Heavy Lift" Archived February 3, 2007, at the Wayback Machine . Boeing, 23 September 2005.
  8. "Bell-Boeing's QTR selected for Heavy Lift study" Archived 2006-08-30 at the Wayback Machine . Boeing, 22 September 2005.
  9. 1 2 3 4 5 6 Fein, Geoff. "Bell-Boeing Quadtiltrotor completes first wind tunnel testing" Archived 2007-09-30 at the Wayback Machine . Defense Daily, 13 October 2006.
  10. "Wind Tunnel testing completed on Bell Boeing quad tiltrotor". Helis.com, September 13, 2006.
  11. "Wind Tunnel testing completed on Bell Boeing quad tiltrotor" Archived January 31, 2007, at the Wayback Machine . Rotorbreeze, p. 14, October 2006.
  12. "Heavy duty: US Army backs tiltrotor as future battlefield airlifter" Archived 2008-01-17 at the Wayback Machine . Flight International, 14 January 2008.
  13. Osborn, Kris. "USAF, Army Merge Heavy-Lift Efforts" [ dead link ]. Defensenews.com, 14 April 2008.
  14. Warwick, Graham. "U.S. Army Extends JHL Concept Studies" Archived 2011-08-12 at the Wayback Machine . Aviation Week, 1 July 2008.
  15. Brannen, Kate. "Pentagon Sheds Some Light on JFTL Effort". Defense News, 15 July 2010.
  16. Joint Future Theatre Lift (JFTL) Technology Study (JTS) Capability Request for Information (CRFI) Archived 2011-09-28 at the Wayback Machine . USAF via fbo.gov, 20 October 2010.
  17. "Joint Future Theater Lift (JFTL) Technology Study (JTS)". US Air Force, 20 October 2010.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.