Pusher configuration

In aeronautical and naval engineering, pusher configuration is the term used to describe a drivetrain of air- or watercraft with its propulsion device(s) after its engine(s). This is in contrast to the more conventional tractor configuration, which places them in front.

The Wright Flyer, a “pusher” aircraft designed in 1903

Though the term is most commonly applied to aircraft, its most ubiquitous propeller example is a common outboard motor for a small boat.

“Pusher configuration” describes the specific (propeller or ducted fan) thrust device attached to a craft, either aerostat (airship) or aerodyne (aircraft, WIG, paramotor, rotorcraft) or others types such as hovercraft, airboat and propeller-driven snowmobiles.[1]

History

1871 Planophore
A Farman MF.11, showing the classic Farman configuration with engine between tail booms
Buhl A-1 Autogyro, the first pusher autogyro
The post-WWII Convair B-36 was unusual in its size, era, number of engines, and combining both propeller and jet propulsion, with six radial piston and four jet engines
Typical of many UAVs, the General Atomics MQ-9 Reaper has a propeller at the extreme tail
NAL Saras, with pushers mounted on pods on either side of the rear fuselage

The rubber-powered "Planophore", designed by Alphonse Pénaud in 1871, was an early successful model aircraft with a pusher propeller.

Many early aircraft (especially biplanes) were "pushers", including the Wright Flyer (1903), the Santos-Dumont 14-bis (1906), the Voisin-Farman I (1907) and the Curtiss Model D used by Eugene Ely for the first ship landing on January 18, 1911. Henri Farman's pusher Farman III and its successors were so influential in Britain that pushers in general became known as the "Farman type".[note 1] Other early pusher configurations were variations on this theme.

The classic "Farman" pusher had the propeller "mounted (just) behind the main lifting surface" with the engine fixed to the lower wing or between the wings, immediately forward of the propeller in a stub fuselage (that also contained the pilot) called a nacelle. The main difficulty with this type of pusher design was attaching the tail (empennage); this needed to be in the same general location as on a tractor aircraft, but its support structure had to avoid the propeller. The earliest examples of pushers relied on a canard but this has serious aerodynamic implications that the early designers were unable to resolve. Typically, mounting the tail was done with a complex wire-braced framework that created a lot of drag. Well before the beginning of the First World War this drag was recognized as just one of the factors that would ensure that a Farman style pusher would have an inferior performance to an otherwise similar tractor type.

The U.S. Army banned pusher aircraft in late 1914 after several pilots died in crashes of aircraft of this type,[2] so from about 1912 onwards the great majority of new U.S. landplane designs were tractor biplanes, with pushers of all types becoming regarded as old fashioned on both sides of the Atlantic. However, new pusher designs continued to be designed right up to the armistice, such as the Vickers Vampire, although few entered service after 1916..

At least up to the end of 1916, however, pushers (such as the Airco DH.2 fighter) were still favoured as gun-carrying aircraft by the British Royal Flying Corps, because a forward-firing gun could be used without being obstructed by the arc of the propeller. With the successful introduction of Fokker's mechanism for synchronising the firing of a machine gun with the blades of a moving propeller,[3] followed quickly by the widespread adoption of synchronisation gears by all the combatants in 1916 and 1917, the tractor configuration became almost universally favoured and pushers were reduced to the tiny minority of new aircraft designs that had a specific reason for using the arrangement. Both the British and French continued to use pusher configured bombers, though there was no clear preference either way until 1917. Such aircraft included (apart from the products of the Farman company itself) the Voisin bombers (3,200 built), the Vickers F.B.5 "Gunbus", and the Royal Aircraft Factory F.E.2, however even these would find themselves being shunted into training roles before disappearing entirely. Possibly the last fighter to use the Farman pusher configuration was the 1931 Vickers Type 161 COW gun fighter.

During the long eclipse of the configuration the use of pusher propellers continued in aircraft which derived a small benefit from the installation and could have been built as tractors. Biplane flying boats, had for some time often been fitted with engines located above the fuselage to offer maximum clearance from the water, often driving pusher propellers to avoid spray and the hazards involved by keeping them well clear of the cockpit. The Supermarine Walrus was a late example of this layout.

The so-called push/pull layout, combining the tractor and pusher configurations—that is, with one or more propellers facing forward and one or more others facing back—was another idea that continues to be used from time to time as a means of reducing the asymmetric effects of an outboard engine failure, such as on the Farman F.222, but at the cost of a severely reduced efficiency on the rear propellers, which were often smaller and attached to lower-powered engines as a result.

By the late 1930s the widespread adoption of all-metal stressed skin construction of aircraft meant, at least in theory, that the aerodynamic penalties that had limited the performance of pushers (and indeed any unconventional layout), were reduced; however any improvement that boosts pusher performance also boosts the performance of conventional aircraft and they remained a rarity in operational service—so the gap was narrowed but was not closed entirely.

During World War II, experiments were conducted with pusher fighters by most of the major powers. Difficulties remained, particularly that a pilot having to bail out of a pusher was liable to pass through the propeller arc. This meant that of all the types concerned, only the relatively conventional Swedish SAAB 21 of 1943 went into series production. Other problems related to the aerodynamics of canard layouts, which had been used on most of the pushers, proved more difficult to resolve.[note 2] One of the world's first ejection seats was (per force) designed for this aircraft, which later re-emerged with a jet engine.

The largest pusher aircraft to fly was the Convair B-36 "Peacemaker" of 1946, which was also the largest bomber ever operated by the United States. It had six 3,800 hp (2,800 kW) 28-cylinder Pratt & Whitney Wasp Major radial engines mounted in the wing, each driving a pusher propeller located behind the trailing edge of the wing, plus four jet engines.

Aero Dynamics Sparrow Hawk II

Although the vast majority of propeller-driven aircraft continue to use a tractor configuration, there has been in recent years something of a revival of interest in pusher designs: in light homebuilt aircraft such as Burt Rutan's canard designs since 1975, ultralights such as the Quad City Challenger (1983), flexwings, paramotors, powered parachutes, and autogyros. The configuration is also often used for unmanned aerial vehicles, due to requirements for a forward fuselage free of any engine interference.

The Aero Dynamics Sparrow Hawk was another homebuilt aircraft constructed chiefly in the 1990s.

Configurations

Airships are the oldest type of pusher aircraft, going back to Frenchman Henri Giffard's pioneering airship of 1852.

Pusher aircraft have been built in many different configurations. In the vast majority of fixed-wing aircraft the propeller or propellers are still located just behind the trailing edge of the "main lifting surface", or below the wing (paramotors) with the engine being located behind the crew position.

Gallaudet D-4 with pusher prop rotating around the rear fuselage

Conventional aircraft layout have a tail (empennage) for stabilization and control. The propeller may be close to the engine, as the usual direct drive:

Rhein Flugzeugbau RW 3 Multoplan with propeller between the rudder and the fin

The engine may be buried in a forward remote location, driving the propeller by drive shaft or belt:

  • The propeller may be located ahead of the tail, behind the wing (Eipper Quicksilver) or inside the airframe (Rhein Flugzeugbau RW 3 Multoplan).
  • The propeller may be located inside the tail, either cruciform or ducted fan (Marvelette).
  • The propeller may be located at the rear, behind a conventional tail (Bede BD-5).
  • The propeller may be located above the fuselage such as on many small flying boats (Lake Buccaneer)
Progenitor to a large number of canard pushers, the experimental Miles M.35 Libellula had its engine at the rear of the fuselage

In canard designs a smaller wing is sited forward of the aircraft's main wing. This class mainly uses a direct drive,[note 3] either single engine, axial propeller[note 4] or twin engines with a symmetrical layout[note 5] or an in line layout (push-pull) as the Rutan Voyager.

Lippisch Delta 1 tailless pusher

In tailless aircraft such as Lippisch Delta 1 and Westland-Hill Pterodactyl type I and IV, horizontal stabilizers at the rear of the aircraft are absent. Flying wings like the Northrop YB-35 are tailless aircraft without distinct fuselage. In these installations, the engines are either mounted in nacelles or the fuselage on tailless aircraft, or buried in the wing on flying wings, driving propellers behind the trailing edge of the wing, often by extension shaft.

Almost without exception flexwing aircraft, paramotors and powered parachutes use a pusher configuration.

Voisin III bomber, the most numerous pusher design, with 3200 built

Other craft with pusher configurations run on flat surfaces, land, water, snow or ice. Thrust is provided by propellers and ducted fans, located to the rear of the vehicle.

  • Hovercraft, lifted by an air cushion, such as the 58 passengers SR.N6.
  • Airboat, flat bottomed vessels planing on water.
  • Aerosledge, also known as the aerosleigh, propeller-driven sledge, or propeller-driven snowmobile.

In aircraft

Advantages

The drive shaft of a pusher engine is in compression in normal operation,[5] which places less stress on it than being in tension in a tractor configuration.

Practical requirements

Flexwing microlight with engine and propeller at the pilot's back

Placing the cockpit forward of the wing to balance the weight of the engine(s) aft improves visibility for the crew. In military aircraft, front armament could be used more easily on account of the gun not needing to synchronize itself with the propeller, although the risk that spent casings fly into the props at the back somewhat offset this advantage.

Aircraft where the engine is carried by, or very close to, the pilot (such as paramotors, powered parachutes, autogyros, and flexwing trikes) place the engine behind the pilot to minimise the danger to the pilot's arms and legs. These two factors mean that this configuration was widely used for early combat aircraft, and remains popular today among ultralight aircraft, unmanned aerial vehicles (UAVs) and radio-controlled airplanes.

Aerodynamics

A pusher may have a shorter fuselage and hence a reduction in both fuselage wetted area and weight.[6]

In contrast to tractor layout, a pusher propeller at the end of the fuselage is stabilizing.[7] A pusher needs less stabilizing vertical tail area[8] and hence presents less weathercock effect;[9] at takeoff roll it is generally less sensitive to crosswind.[note 6][10][11]

When there is no tail within the slipstream, unlike a tractor there is no rotating propwash around the fuselage inducing a side force to the fin. At takeoff, a canard pusher pilot does not have to apply rudder input to balance this moment.[12]

Efficiency can be gained by mounting a propeller behind the fuselage, because it re-energizes the boundary layer developed on the body, and reduces the form drag by keeping the flow attached to the fuselage. However, it is usually a minor gain compared to the airframe's detrimental effect on propeller efficiency.[8]

Wing profile drag may be reduced due to the absence of prop-wash over any section of the wing.

Safety

The engine is mounted behind the crew and passenger compartments, so fuel oil and coolant leak will vent behind the aircraft, and any engine fire will be directed behind the aircraft. Similarly, propeller failure is less likely to directly endanger the crew.

A pusher ducted fan system offers a supplementary safety feature attributed to enclosing the rotating fan in the duct, therefore making it an attractive option for various advanced unmanned air vehicle configurations or for small/personal air vehicles or for aircraft models.[13]

Structural and weight considerations

SAAB J 21 fighter, with the pusher propeller mounted between two fuselage booms

A pusher design with an empennage behind the propeller is structurally more complex than a similar tractor type. The increased weight and drag degrades performance compared with a similar tractor type. Modern aerodynamic knowledge and construction methods may reduce but never eliminate the difference. A remote or buried engine requires a drive shaft and associated bearings and supports, torsional vibration control, and adds weight and complexity.[14][15]

Center of gravity and landing gear considerations

To maintain a safe center of gravity (CG) position, there is a limit to how far aft an engine can be installed.[16] The forward location of the crew may balance the engine weight and will help determine the CG. As the CG location must be kept within defined limits for safe operation load distribution must be evaluated before each flight.[17][note 7]

Due to a generally high thrust line needed for propeller ground clearance, negative (down) pitching moments, and in some cases the absence of prop-wash over the tail, a higher speed and a longer roll may be required for takeoff compared to tractor aircraft.[18][19][20] The Rutan answer to this problem is to lower the nose of the aircraft at rest such that the empty center of gravity is then ahead of the main wheels. In autogyros a high thrust line results in a control hazard known as power push-over.

Aerodynamic considerations

The Supermarine Walrus pusher flying boat is a typical flying boat, with the engine mounted high to avoid spray; however, throttle changes then induce pitch changes.

Due to the generally high thrust line to ensure ground clearance, a low wing pusher layout may suffer power change induced pitch changes, also known as pitch/power coupling. Pusher seaplanes with especially high thrust lines and tailwheels may find the vertical tail masked from the airflow, severely reducing control at low speeds, such as when taxiing. The absence of prop-wash over the wing reduces the lift and increases takeoff roll length.[21] Pusher engines mounted on the wing may obstruct sections of the wing trailing edge, reducing the total width available for control surfaces such as flaps and ailerons. When a propeller is mounted in front of the tail, changes in engine power alter the airflow over the tail and can give strong pitch or yaw changes.

Propeller ground clearance and foreign object damage

Due to the pitch rotation at takeoff, the propeller diameter may have to be reduced (with a loss of efficiency[22]) and/or landing gear made longer[6] and heavier. Many pushers[note 8] have ventral fins or skids beneath the propeller to prevent the propeller from striking the ground at an added cost in drag and weight. On tailless pushers such as the Rutan Long-EZ the propeller arc is very close to the ground while flying nose-high during takeoff or landing. Objects on the ground kicked up by the wheels can pass through the propeller disc, causing damage or accelerated wear to the blades or, in extreme cases, the blades may strike the ground.

When an airplane flies in icing conditions, ice can accumulate on the wings. If an airplane with wing-mounted pusher engines experiences icing, the props will ingest shedded chunks of ice, endangering the propeller blades and parts of the airframe that can be struck by ice violently redirected by the props. In early pusher combat aircraft, spent ammunition casings caused similar problems, and devices for collecting them had to be devised.

Propeller efficiency and noise

The propeller passes through the fuselage wake, wing and other flight surface downwashes—moving asymmetrically through a disk of irregular airspeed. This reduces propeller efficiency and causes vibration inducing structural propeller fatigue[note 9] and noise.

Prop efficiency is usually at least 2–5% less and in some cases more than 15% less than an equivalent tractor installation.[23] Fullscale wind tunnel investigation of the canard Rutan VariEze showed a propeller efficiency of 0.75 compared to 0.85 for a tractor configuration, a loss of 12%.[24] Pusher props are noisy,[14] and cabin noise may be higher than tractor equivalent (Cessna XMC vs Cessna 152).[25] Propeller noise may increase because the engine exhaust flows through the props. This effect may be particularly pronounced when using turboprop engines due to the large volume of exhaust they produce.[8]

Engine cooling and exhaust

Power-plant cooling design is more complex in pusher engines than for the tractor configuration, where the propeller forces air over the engine or radiator. Some aviation engines have experienced cooling problems when used as pushers.[25] To counter this, auxiliary fans may be installed, adding additional weight. The engine of a pusher exhausts forward of the propeller, and in this case the exhaust may contribute to corrosion or other damage to the propeller. This is usually minimal, and may be mainly visible in the form of soot stains on the blades.

Propeller
Piaggio P.180 Avanti with engines mounted on the wing trailing edge, away from passengers, allowing safer boarding.

In case of propeller/tail proximity, a blade break can hit the tail or produce destructive vibrations leading to a loss of control.[26]

Crew members risk striking the propeller while attempting to bail out of a single-engined airplane with a pusher prop.[27] At least one early ejector seat was designed specifically to counter this risk. Some modern light aircraft include a parachute system that saves the entire aircraft, thus averting the need to bail out.

Engine

Engine location in the pusher configuration might endanger the aircraft's occupants in a crash or crash-landing in which engine momentum projects through the cabin. For example, with the engine placed directly behind the cabin, during a nose-on impact the engine momentum may carry the engine through the firewall and cabin, and might injure some cabin occupant(s).[note 10]

Aircraft loading

Spinning propellers are always a hazard on ground working, such as loading or embarking the airplane. Tractor configuration leaves the rear of the plane as relatively safe working area, while a pusher is dangerous to approach from behind, while a spinning propeller may suck in things and people nearby in front of it with fatal results to both the plane and the people sucked in. Even more hazardous are unloading operations, especially mid-air, such as dropping supplies on parachute or skydiving operations, which are next to impossible with a pusher configuration airplane, especially if propellers are mounted on fuselage or sponsons.

See also

References

Notes

  1. The Royal Aircraft Factory referred to all the early pushers they built as Farman Experimentals - or F.E.s.
  2. See stability issues of the Curtiss-Wright XP-55 Ascender
  3. An exception is the Raptor Aircraft Raptor whose Audi V6 diesel engine drives the propeller via PRSU belts.
  4. Canard aircraft: wartime Curtiss-Wright XP-55 Ascender and Japanese Kyushu J7W (with a drive shaft), Ambrosini SS.4; Rutan VariEze and Long-EZ, AASI Jetcruzer
  5. Canard symmetrical layout: Wright Flyer, Beechcraft Starship
  6. Because of less weathercock stability
  7. In the case of the Cozy IV, a side-by-side four-seater, an absent copilot must be balanced with 20 kg (40 lb) in the nose of the aircraft (Cafe Aircraft Performance Report)
  8. Dornier Do 335, LearAvia Lear Fan, Prescott Pusher, Grob GF 200, Beechcraft Starship, Vmax Probe
  9. The only approved prop for the Rutan pushers is wood, which is more resistant to fatigue damage.
  10. Crash of Ambrosini SS.4

Citations

  1. "Propeller-Driven Sleighs". The Museum of RetroTechnology. Archived from the original on 10 July 2011. Retrieved 10 September 2008.
  2. "Propeller Configurations". www.centennialofflight.net. US Centennial of Flight Commission. Archived from the original on 2014-01-21.
  3. Guttman, Jon (10 September 2009). Pusher Aces of World War 1. Illustrated by Harry Dempsey. Oxford, England: Osprey Publishing. pp. 6–7. ISBN 9781846034176.
  4. Luna, Andres D. (29 May 2010). "Aviation Photo #1880962: Embraer-FMA CBA-123 Vector - Embraer". Airliners.net. Archived from the original on 12 September 2011.
  5. Gunston, Bill (10 May 2004). The Cambridge Aerospace Dictionary. Cambridge University Press. p. 480. ISBN 978-0521841405.
  6. Raymer, Daniel P. (1989). Aircraft Design: A Conceptual Approach. Reston, Virginia: American Institute of Aeronautics & Astronautics. pp. 222–223. ISBN 9781600869112.
  7. Hoerner, Sighard (1975). "XIII Directional characteristics of aeroplanes: IV Influence of Propulsion". Fluid-Dynamic Lift: Practical Information on Aerodynamic and Hydrodynamic Lift. p. 17. Bibcode:1975STIA...7632167H. {{cite book}}: |journal= ignored (help)
  8. Stackhouse, Don. "Don discusses propeller effects in detail..." Archived from the original on 21 November 2011. Retrieved 15 October 2011.
  9. Roskam, Jan (1999). Airplane Design Part II: Preliminary Configuration Design and Integration of the Propulsion System. Vol. 2. Lawrence, Kansas: Design, Analysis and Research Corporation. p. 132. ISBN 9781884885433.
  10. "Grob tests highlight exhaust problem", Flight International: 11, 24–30 June 1992, archived from the original on 20 May 2011
  11. Brown, Philip W. (1 October 1987). Flight test Results for Several Light, Canard-Configured airplanes (Technical report). NASA Langley Research Center. doi:10.4271/871801. eISSN 2688-3627. ISSN 0148-7191.
  12. Stinton, Darrol (1983). "Propeller Effects". The Design of the Aeroplane. St Albans, Hertfordshire, England: Granada Publishing. pp. 304–307. ISBN 9780632018772.
  13. Abrego, Anita I.; Bulaga, Robert W. (23 January 2002). "Performance study of a ducted fan system" (PDF). American Helicopter Society International, Inc. Archived from the original (PDF) on 18 October 2011.
  14. Garrison, Peter (29 June 2009). "Technicalities". Flying. Archived from the original on 29 March 2012. Retrieved 12 October 2011.
  15. Hassenaur, Donald P. (1 January 1996). "Propeller Drive Systems and Torsional Vibration". Alternative Engines. Vol. 1. compiled by Mick Myal. Phoenix, Arizona: Fiesta Publishing. pp. 167–172. ISBN 9780964361324.
  16. McClellan, J. Mac (24 June 2006). "Flashback to 1981: A Look Back at the Lear Fan". Flying. Archived from the original on 5 September 2011. Retrieved 20 October 2011.
  17. Seeley, Brien; Stephens, C.J. "Cozy Mk IV" (PDF). Aircraft Performance Reports. The CAFE Board. CAFE Foundation. Archived from the original (PDF) on 27 October 2010.
  18. Odum, David (2003). "Oshkosh 2003 Scrapbook". www.airplanezone.com. Airplane Zone. Archived from the original on 25 April 2012.
  19. http://www.kitplanes.com/magazine/pdfs/Grinvalds_Orion_0409.pdfOrion%5B%5D V1(rotation speed): 65 kn
  20. Berven, Lester H. BD-5 Flight Test Program Report (Technical report). Bede Aircraft Corporation. Archived from the original on 19 November 2011 via Journal of the Society Of Experimental Test Pilots.
  21. Hoerner, Sighard F.; Habul, Dr. -Ing; Borst, Henry V. (1985). "XII: Propulsion Lift and Stability, 2. Influence of Propeller Slipstream on Wings". Fluid Dynamic Lift: Practical Information on Aerodynamic and Hydrodynamic Lift (PDF) (2nd ed.). p. 12-8. Archived (PDF) from the original on 8 May 2021.
  22. Abzug, Malcolm J.; Larrabee, E. Eugene (2002). Airplane Stability and Control: A History of the Technologies that Made Aviation Possible. Cambridge University Press. p. 257. doi:10.1017/CBO9780511607141. ISBN 9780511607141.
  23. Stackhouse, Don. "Al Bowers gave us an excellent explanation of the stability issues of a tractor vs. pusher installation. However, there are some other issues that need to be considered". Archived from the original on 21 November 2011. Retrieved 25 September 2011.
  24. Yip, Long P.; Coy, Paul F. (March 1985). Wind-Tunnel Investigation of a Full-Scale Canard-Configured General Aviation Airplane (PDF) (Technical report). Hampton, Virginia: NASA Langley Research Center. Archived (PDF) from the original on 8 May 2021.
  25. Visschedijk, Johan; Tilborg, Walter van; Smith, Karl (14 December 2003). "Cessna XMC". 1000aircraftphotos.com. Archived from the original on 30 January 2008.
  26. Grinvalds Orion crash in 1985, Experimental magazine n°2, March 1986, pages 20-24, Extrait du Rapport d'expertise: "La cause initiale de l'accident la plus probable est la rupture du mécanisme de commande de pas d'une pale de l'hélice. Cette rupture a a engendré des vibrations importantes de la partie arrière de l'avion... ruptures structurales... privant les pilotes des commandes de vol de profondeur et de direction". Failure of the pitch command system of one blade, important propeller vibrations, structural break, loss of pitch and yaw control
  27. Brown, Eric (1961). "Chapter 10". Wings on My Sleeve. London, England: Weidenfeld & Nicolson. pp. 150–151. ISBN 9780753822098.

Sources

  • Abzug, Malcolm J.; Larrabee, E. Eugene (2005). Airplane Stability and Control: A History of the Technologies That Made Aviation Possible. Cambridge Aerospace Series 14 (2nd ed.). Cambridge, UK: Cambridge University Press. ISBN 978-0521809924.
  • Gunston, Bill (2004). The Cambridge Aerospace Dictionary Cambridge. Cambridge University Press. p. 480. ISBN 978-0521841405.
  • Guttman, Jon (2009). Pusher Aces of World War 1. Osprey Aircraft of the Aces 88. Oxford, UK: Osprey. ISBN 978-1846034176.
  • Hoerner, Gihard F.; Borst, Henry V. (1985). Fluid-Dynamic Lift - Practical Information on Aerodynamic and Hydrodynamic Lift. Brick Town, New Jersey: Mrs. Liselotte Hoerner. LCCN 75-17441.
  • Raymer, Daniel P. (1992). Aircraft Design: A Conceptual Approach. AIAA Education Series. Washington, DC: American Institute of Aeronautics and Astronautics. ISBN 978-0930403515.
  • Stinton, Daroll (1983). The Design of the Aeroplane. Oxford, UK: BSP Professional Books. ISBN 978-0632018772.
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