Three-surface aircraft

A three-surface aircraft or sometimes three-lifting-surface aircraft has a foreplane, a central wing and a tailplane. The central wing surface always provides lift and is usually the largest, while the functions of the fore and aft planes may vary between types and may include lift, control and/or stability.

A Piaggio P.180 Avanti showing its three lifting surfaces

In civil aircraft the three surface configuration may be used to give safe stalling characteristics and short takeoff and landing (STOL) performance. It is also claimed to allow minimizing the total wing surface area, reducing the accompanying skin drag. In combat aircraft this configuration may also be used to enhance maneuverability both before and beyond the stall, often in conjunction with vectored thrust.

History

An early designation used in 1911 was "three plane system".[1] The Fernic designs of the 1920s were referred to as "tandem". While there are indeed two lifting wing surfaces in tandem, the tailplane forms a third horizontal surface.

Pioneer experiments

During the pioneer years of aviation a number of aircraft were flown with both fore and aft auxiliary surfaces. The issue of control vs. stability was poorly understood and typically pitch control was on the front surface with the rear surface also lifting, leading to instability in pitch. The Kress Drachenflieger of 1901 and Dufaux triplane of 1908 had insufficient power to take off. More successful types included the Voisin-Farman I (1907) and Curtiss No. 1 (1909). The Wright Brothers too experimented on the basic Flyer design in an effort to obtain both controllability and stability, flying it at various times in first canard, then three surface and finally conventional configurations.[2][3] By the outbreak of the First World War in 1914, the main wing with smaller rear tail surface had become the conventional configuration and few three surface types would be flown for many years. The Fokker V.8 of 1917 and Caproni Ca.60 Noviplano of 1921 were both failures.

Soft stall and STOL

In 1920s George Fernic developed the idea of two lifting surfaces in tandem, together with a conventional tailplane. The small foreplane was highly loaded and as the angle of attack increased it was designed to stall first, causing the nose to drop and allowing the aircraft to recover safely without stalling the main wing. This "soft" stall provides a level of safety in the stall which is not usually present in conventional designs. The Fernic T-9, a three-surface monoplane, flew in 1929. Fernic was killed in an accident while flying its successor the FT-10 Cruisaire.[4]

It is possible to achieve such a soft stall with a pure canard design, but it is then difficult to control the pitching and oscillations can develop as the foreplane repeatedly lifts the nose, stalls and recovers. Also, care must be taken in the design that the turbulent wake from the stalled foreplane does not in itself disturb the airflow over the main wing sufficiently to cause significant loss of lift and cancel out the nose-down pitching moment. In the three-surface design the third, tail surface does not stall and provides better controllability.

In the 1950s James Robertson developed his experimental Skyshark. This was a broadly conventional design but with a variety of features, including a small canard foreplane, intended to give not only a safe stall but good Short takeoff and landing (STOL) performance. The foreplane allowed STOL performance to be achieved without the high angles of attack and accompanying dangers of stalling required by conventional STOL designs. The aircraft was evaluated by the US Army.[5] Robertson's system was commercialised as the Wren 460, a modified Cessna light aircraft. This in turn was later licensed and produced during the 1980s as the Peterson 260SE and with the foreplane modification only as the 230SE. In 2006 a ruggedised variant, the Peterson Katmai, entered production. A broadly similar approach is taken by the 1988 Eagle-XTS[6] and its derivatives, the Eagle 150 series.

Manoeuvrability beyond the stall

Grumman X-29, rear strake flaps deflected

Around 1979, military jet designers began studying three-surface configurations as a way to provide enhanced manoeuvrability and control, especially at low speeds and high angles of attack such as during takeoff and combat.[7] In the United States the experimental Grumman X-29 flew in 1984 and a modified McDonnell Douglas F-15, the F-15 STOL/MTD, in 1988 but these designs were not followed up. In the Soviet Union a Sukhoi Su-27 modified with canard foreplanes flew in 1985[8] and derivatives of this design became the only military three-surface types to enter production.

Minimum wing surface

Also in 1979, Piaggio began design studies on a three-surface civil twin turboprop which, in collaboration with Learjet, would emerge as the Piaggio P.180 Avanti. This type first flew in 1986 and entered service in 1990, with production continuing today. In the Avanti, the three-surface configuration is claimed to significantly reduce wing size, weight and drag compared to the conventional equivalent.[9]

Two experimental aircraft adopting this configuration were subsequently built by Scaled Composites under the lead of Burt Rutan and flown in 1988. The Triumph was a twin-turbofan very light jet aircraft designed for Beechcraft. Flight testing validated the targeted performance range.[10][11] The Catbird was a single-engined propeller-driven aircraft, envisioned by Rutan as a replacement for the Beechcraft Bonanza. It holds the world record for speed over a closed circuit of 5,000 km (3,100 mi) without payload of 334.44 km/h (207.81 mph) set in 2014.[12]

Fighter aircraft design

Some advanced jet aircraft have a three-surface configuration, often in conjunction with thrust vectoring. This is typically intended to enhance control and manoeuvrability, especially at very high angles of attack beyond the stall point of the main wing. Some advanced combat manoeuvres such as Pugachev's Cobra and the Kulbit were first performed on Sukhoi three-surface aircraft.

The experimental Grumman X-29 was of basic "tail-first" canard configuration, with unusual forward-swept wings and strakes extending rearwards from the main wing roots. Movable flaps at the ends of the strakes effectively made it a three-surface design.[13] The X-29 demonstrated exceptional high-angle of attack manoeuvrability.[14]

A more straightforward three-surface design is seen in several variants of the otherwise conventional Sukhoi Su-27. Following the successful addition of canard foreplanes to a development aircraft, these were incorporated into a number of subsequent production variants including the naval Su-33 (Su-27K), some Su-30s, the Su-35 and the Su-37. The Chinese Shenyang J-15 also inherits the configuration of the Su-33.

The McDonnell Douglas F-15 STOL/MTD was an F-15 airframe modified with canard foreplanes and thrust vectoring, designed to demonstrate these technologies for both STOL performance and high manoeuvrability.

Reduced surface area design

Equilibrium of a conventional (top) and a three surface aircraft (bottom)

The three-surface configuration is claimed to reduce total aerodynamic surface area compared to the conventional and canard configurations,[9][15] thus enabling drag and weight reductions.

Pitch equilibrium

On most aircraft, the wing centre of pressure moves forward and backward according to flight conditions. If it does not align with the centre of gravity, a corrective or trim force must be applied to prevent the aircraft pitching and thus to maintain equilibrium.[16]

On a conventional aircraft this pitch trim force is applied by a tailplane. On many modern designs, the wing centre of pressure is normally aft of the centre of gravity, so the tailplane must exert a downward force.[17] Any such negative lift generated by the tail must be compensated by additional lift from the main wing, thus increasing wing area, drag, and weight requirements.

On a three-surface aircraft, the pitch trim forces can be shared, as needed in flight, between the foreplane and tailplane. Equilibrium can be achieved with lift from the foreplane rather than downforce from the tailplane. Both effects, the reduced downforce and the extra lifting force, reduce the load on the main wing.

The Piaggio P.180 Avanti has flaps on both its forward wing and main wing. Both flaps deploy in concert to maintain pitch neutrality for take-off and landing.[9]

Static stability and the stall

On a canard aircraft, to allow natural static pitch stability in normal flight, the foreplane must provide lift. Also, in order for the aircraft to have safe stall characteristics the foreplane must stall before the main wing, pitching the aircraft down and allowing the aircraft to recover. This means that a safety margin must be used on the main wing area so that its maximum lift coefficient and wing loading are never attained in practice. This in turn means that the main wing must be increased in size.

On a three-surface aircraft, the tailplane acts as a conventional horizontal stabiliser. In the stall condition, even if the main wing is stalled the tailplane can provide a pitch-down moment and allow recovery. The wing may thus be used up to its maximum lift coefficient, an advantage that may translate into a reduction of its area and weight.

A lifting foreplane is positioned ahead of the centre of gravity, so its lift moment acts in the same direction as any movement in pitch. If the aircraft is to be naturally stable, the foreplane's size, lift slope and moment arm must be chosen so that it does not overpower the stabilizing moment provided by the wing and tailplane. Stability constraints thus limit the foreplane's volume ratio (a measure of its effectiveness in trim and stability terms), which may in turn limit its ability to share pitch trim forces as described above.

Wing area reduction

The minimum size of the lifting wings of an aircraft is determined by: the weight of the aircraft, the force required to oppose the negative lift produced by the horizontal stabilizer, the targeted take off and landing speeds, and the coefficient of lift of the wings.

Most modern aircraft use trailing edge flaps on the main wing to increase the wings lift coefficient during takeoff and landing; thus allowing the wing to be smaller than it would otherwise need to be. This may reduce the weight of the wing, and it always reduces the surface area of the wing. The reduction of surface area proportionately reduces skin drag at all speeds.

A drawback of the use of trailing edge flaps is that they produce significant negative pitching moment when in use. In order to balance this pitching moment the horizontal stabilizer must be somewhat larger than it would otherwise be, so that it can produce enough force to balance the negative pitching moment created by the trailing edge flaps. This, in turn, means that the main wing must be somewhat larger than it would otherwise have to be to balance the larger negative lift produced by the larger horizontal stabilizer.

On a canard aircraft the foreplane can provide positive lift at takeoff, reducing some of the down force the rear stabilizer would otherwise have to create. However, the main wing must be large enough to not only lift the aircraft's remaining weight at takeoff but also to provide adequate safety margin to prevent stalling. On a three-surface aircraft, neither of these handicaps is present and the main wing can be reduced in size, so also reducing weight and drag. It is claimed that the total area of all wing surfaces of a three-surface aircraft can be less than that of the equivalent two-surface aircraft, so reducing both weight and drag.

Minimum area in cruise can be further reduced through the use of conventional high-lift devices such as flaps, allowing a three-surface design to have minimum surface area at all points in the flight envelope.[9]

Examples of reduced-area three-surface aircraft include the Piaggio P.180 Avanti, and the Scaled Composites Triumph and Catbird. These aircraft were designed to expose a minimum of total surface area to the slipstream; thus reducing surface drag for speed and fuel efficiency. Several reviews compare the Avanti's top speed and service ceiling to that of lower-end jet aircraft, and report significantly better fuel efficiency at cruise speed.[18][19] Piaggio attributes this performance in part to the layout of the aircraft, claiming a 34% reduction in total wing area compared to a conventional layout.[9][15]

List of three-surface aircraft

TypeCountryClassRoleDateStatusNo.Notes
Aceair AERIKS 200SwitzerlandPropellerPrivate2002PrototypeDesigned as a homebuild kit.
Curtiss/AEA June BugUSPropellerExperimental1908Prototype
Caproni Ca.60 NoviplanoItalyPropellerTransport1921PrototypeThree triplane stacks, making nine wings in all. Flying boat.
Curtiss No. 1USPropellerExperimental1909PrototypeAlso known as the Curtiss Gold Bug or Curtiss Golden Flyer.
de la Farge PulgaArgentinaPropellerPrivatecirca 1990Modified Flying Flea[20]
DufauxSwitzerlandPropellerExperimental1908PrototypeFirst Swiss aircraft to fly.[21]
Eagle-XTSAustraliaPropellerPrivate1988
Eagle Aircraft Eagle 150AustraliaPropellerPrivate1997
Farman three wing monoplaneFrancePropellerExperimental1908Prototype[21]
Fernic T-9USPropellerPrivate1929
Fernic-Cruisaire FT-10USPropellerPrivate1930[22][23]
Fokker V.8GermanyPropellerExperimental1917Prototype
Grumman X-29USJetExperimental1984PrototypeForward-swept wing with canard foreplane and tailboom flaps.
Herring-BurgessUSPropeller1910Biplane.[24][25]
Kress DrachenfliegerAustria-HungaryPropellerExperimental1901PrototypeFailed to fly: engine lacked sufficient power to take off.
McDonnell Douglas F-15 STOL/MTDUSJetExperimental1988Prototypetechnology demonstrator of enhanced maneuverability including use of thrust vectoring
Mikoyan-Gurevich Ye-8Soviet UnionJetExperimental1962Prototype
Miller-Bohannon JM-2 Pushy GaloreUSPropellerPrivate1989Operational1Racer in pusher configuration
NPO Molniya 1RussiaTransport1992
Peterson 260SE and 230SEUSPropellerPrivate1986
Peterson KatmaiUSPropellerPrivate
Piaggio P.180 AvantiItalyPropellerTransport1986Production
Robertson SkysharkUSPropellerPrivate
Rutan Scaled Model 120 'Predator'USPropellerExperimental1984Prototype[26]
Scaled Composites ATTT (model 133)USPropellerExperimental1987Prototype[27]
Scaled Composites Triumph (model 143)USJetExperimental1988Prototype
Scaled Composites Catbird (model 181)USPropellerExperimental1988Prototype
Shenyang J-15ChinaJetHigh-manoeuvrability combat2009
Short No.1 biplaneUKPropellerExperimental1910PrototypeNot flown.
Sukhoi Su-27MSoviet UnionJetHigh-manoeuvrability combatSome examples fitted with a foreplane in addition to the standard tailplane.
Sukhoi Su-30 MKIIndiaJetFighter1989ProductionLicense-built variant of the Sukhoi Su-30
Sukhoi Su-33Soviet UnionJetFighter1987Production
Sukhoi Su-34RussiaJetAttack1990Production
Sukhoi Su-37RussiaJetFighter1996Prototype
Sukhoi Su-47RussiaJetExperimental1997PrototypeMain wing is forward-swept.
Voisin-Farman IFrancePropellerExperimental1907
Wren 460USPropellerPrivate1963
Wright Model A (Modified)USPropellerExperimental1909[3]

See also

References

Notes

  1. G.H. Bryan, Stability in Aviation, 1911
  2. Culick, F.E.C. (June 2003). "The Wright Brothers: First Aeronautical Engineers and Test Pilots" (PDF). AIAA Journal. 41 (6): 1003–1004. Bibcode:2003AIAAJ..41..985C. CiteSeerX 10.1.1.579.7665. doi:10.2514/2.2046. Retrieved 13 July 2013.
  3. Engler, N. "1909-1910 Wright Model AB". wright-brothers.org. The Wright Brothers Aeroplane Company.
  4. "Fernic T.10 Cruisaire". 1000aircraftphotos.com. Retrieved 3 May 2015.
  5. "Sport and Business - Introducing the Wren" (PDF). Flight International. 23 May 1963. p. 751. Retrieved 14 July 2013.
  6. "Australian Eagle-XTS set to take off through Malaysian joint venture" (PDF). Flight International. 27 November 1991. p. 18. Retrieved 14 July 2013.
  7. Miller, J.; The X-planes, Speciality Press (1983), page 178.
  8. Green, W. & Swanborough, S.; The complete book of fighters, Salamander (1994).
  9. "Piaggio P180 Avanti II Specification and Description" (PDF). Piaggio Aero. January 2005.
  10. "Scaled Composites project: Triumph". Scaled Composites website. Scaled Composites. Retrieved 14 July 2013.
  11. Bailey, John (30 January 1991), "Rutan on the Attack" (pdf), Flight International, Reed Business Publishing, vol. 139, no. 4252, p. 30, retrieved 14 July 2013
  12. FAI Record File Num #17236, FAI
  13. In Jan Roskam's Airplane Design, the X-29 is described as a three-surface aircraft
  14. "NASA Dryden Fact Sheet - X-29". NASA Dryden Flight Research Center website. NASA. 15 December 2009. Retrieved 14 July 2013.
  15. Mazzoni, Alessandro (27 May 1982). "United States Patent 4,746,081". USPTO database. Retrieved 11 July 2013.
  16. Phillips, Warren F. (2010). "4.1 Fundamentals of Static Equilibrium and Stability". Mechanics of Flight (2nd ed.). Hoboken, New Jersey: Wiley & Sons. p. 377. ISBN 978-0-470-53975-0. When the controls are set so that the resultant forces and the moments about the center of gravity are all zero, the aircraft is said to be in trim, which simply means static equilibrium
  17. Barnard, R.H.; Philpott, D.R. (2010). "11. Static stability". Aircraft Flight (4th ed.). Harlow, England: Prentice Hall. p. 275. ISBN 978-0-273-73098-9.
  18. Goyer, Robert (19 April 2012). "Piaggio P.180 Avanti II (review)". Flying magazine. Retrieved 14 July 2013.
  19. Collins, Peter (1 November 2005). "Flight Test: Piaggio Avanti II - Hard to beat". Flight International. Retrieved 14 July 2013.
  20. "Pou-Guide - Les "Pulgas" argentins". pouguide.org. Retrieved 3 May 2015.
  21. Jane, F.T.; All the world's aircraft 1913, Sampson Low, 1913, facsimile reprint David & Charles, 1969.
  22. Le Document Aéronautique n°52, July 1930, page 440
  23. Photo of a Fernic-Cruisaire FT-10, Aerofiles, retrieved 3 May 2015
  24. Taking Off: Pioneering New England Aviation, 1910, Historic New England web site (Retrieved 5 October 2014).
  25. Herring-Burgess Biplane Archived 6 October 2014 at the Wayback Machine, Smithsonian National Air and Space Museum web site (Retrieved 5 October 2014).
  26. "ADVANCED TECHNOLOGY 'Predator 480'". Archived from the original on 29 January 2012. Retrieved 15 April 2013.
  27. "SCALED Model 133 'SMUT' (ATTT or AT3)". Archived from the original on 29 May 2013. Retrieved 15 April 2013.

Bibliography

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