Monoplane

Supermarine Spitfire monoplane

A monoplane is a fixed-wing aircraft with a single main wing plane, in contrast to a biplane or other multiplane, each of which has multiple planes.

A monoplane has inherently the highest efficiency and lowest drag of any wing configuration and is the simplest to build. However, during the early years of flight these advantages were offset by its greater weight and lower manoeuvrability, making it relatively rare until the 1930s.[1] Since then the monoplane has been the most common form for a fixed-wing aircraft.

History

The Santos-Dumont Demoiselle was the first production monoplane (replica shown).

Although the first successful aircraft were biplanes, the first attempts at heavier-than-air flying machines were monoplanes, and many pioneers continued to develop monoplane designs. For example, the first aeroplane to be put into production was the 1907 Santos-Dumont Demoiselle, while the Blériot XI flew across the English Channel in 1909. Throughout 1909–1910 Hubert Latham set multiple altitude records in his Antoinette IV monoplane, eventually reaching 1,384 m (4,541 ft).[2]

The Junkers J1 monoplane pioneered all-metal construction in 1915.

The equivalent German language term is Eindecker, as in the mid-wing Fokker Eindecker fighter of 1915 which for a time dominated the skies in what became known as the "Fokker scourge". The German military Idflieg aircraft designation system prior to 1918 prefixed monoplane type designations with an E, until the approval of the Fokker D.VIII fighter from its former "E.V" designation. However the success of the Fokker was short-lived and World War I was dominated by biplanes. Towards the end of the war the parasol monoplane became popular and successful designs were produced into the 1920s.

Nonetheless, relatively few monoplane types were built between 1914 and the late 1920s, compared with the number of biplanes. The reasons for this were primarily practical. With the low engine powers and airspeeds available, the wings of a monoplane needed to be large in order to create enough lift while a biplane could have two smaller wings and so be made smaller and lighter.

Towards the end of the first world war, the inherent high drag of the biplane was beginning to restrict performance. Engines were not yet powerful enough to make the heavy cantilever-wing monoplane viable and the braced parasol wing became popular on fighter aircraft, although few arrived in time to see combat. It remained popular throughout the 1920s.

On flying boats with a shallow hull, a parasol wing allows the engines to be mounted above the spray from the water when taking off and landing. It was popular on flying boats during the 1930s; a typical example being the Consolidated Catalina. It died out when taller hulls became the norm during World War II, allowing the wing to be attached directly to the hull.

As ever-increasing engine powers made the weight of all-metal construction and the cantilever wing more practical, they became common during the post-World War I period, the day of the braced wing passed, and by the 1930s the cantilever monoplane was fast becoming the standard configuration for a fixed-wing aircraft. Advanced monoplane fighter-aircraft designs were mass-produced for military services around the world in both the Soviet Union and the United States in the early-mid 1930s, with the Polikarpov I-16 and the Boeing P-26 Peashooter respectively.

Most military aircraft of WW2 were monoplanes, as have been virtually all aircraft since.

Jet and rocket engines have even more power and all modern high-speed aircraft, especially supersonic types, have been monoplanes.

Monoplane characteristics

Support and weight

The inherent efficiency of the monoplane can best be realised in the unbraced cantilever wing which carries all structural forces internally. By contrast a braced wing has additional drag from the exposed bracing struts and/or wires, leading to lower aerodynamic efficiency. On the other hand, the braced wing has greater structural efficiency and can be made much lighter. This in turn means that for a wing of a given size, bracing allows it to fly slower with a lower-powered engine, while a heavy cantilever wing needs a more powerful engine and can fly faster.[3]

A cantilever wing can be made lighter by making it thicker. This increases internal storage for fuel, retractable undercarriage, armaments and in some cases even passengers and crew. A thick wing can also be given greater curvature of its upper surface and so create more lift than a thin wing, and some American bombers of World War II had unusually thick wings.

But thickness, like bracing, also increases drag, especially above the speed of sound. Supersonic aircraft have thin wings which are much heavier, and the wheels and fuel must find storage elsewhere.

Monoplane vs. biplane

The earliest powered aircraft were biplanes, and this configuration was dominant until the mid-1920s, when the monoplane began to take over. Today, the biplane configuration is seldom used, although special types including aerobatic aircraft and kit planes are still available.

It might seem that a monoplane's wing should be double the area of the equivalent biplane wing, because the biplane has twice as many. This ought to make the monoplane wing larger and more unwieldy, but in practice the biplane's wings interfere with each other, making them less aerodynamically efficient and reducing any theoretical advantage.

A pair of biplane wings is typically braced with struts and wires to stiffen the structure and make it lighter, thereby enabling slow flight. However, even a strutted monoplane will still be aerodynamically more efficient than a biplane.

Human-powered aircraft, which are among the slowest and lightest of flying machines, are monoplanes with very large wings.

Wing position

Besides the general variations in wing configuration such as tail position and use of bracing, the main distinction between types of monoplane is how high up the wings are mounted in relation to the fuselage.

Low wing

Low wing on a Curtiss P-40

A low wing is one which is located on or near the base of the fuselage.

Placing the wing low down allows good visibility upwards and frees up the central fuselage from the wing spar carry-through. By reducing pendulum stability it makes the aircraft more manoeuvrable, as on the Spitfire; but aircraft that value stability over manoeuvrability may then need some dihedral. A low wing allows a lighter structure because the fuselage sides carry no additional loads, and the main undercarriage legs can be made shorter.

A feature of the low wing position is its significant ground effect, giving the plane a tendency to float further before landing.[4][5] Conversely, this very ground effect permits shorter takeoffs.

The low wing configuration has proved particularly suitable for passenger jetliners.

Mid wing

Mid wing on a de Havilland Vampire T11.

A mid wing is mounted midway up the fuselage. It is aerodynamically the cleanest and most balanced, but the carry-through spar structure can reduce the useful fuselage volume near its centre of gravity, where space is often in most demand. It is common on high-performance types such as sailplanes.

Shoulder wing

Shoulder wing on an ARV Super2.

A shoulder wing (a category between high-wing and mid-wing) is a configuration whereby the wing is mounted near the top of the fuselage, but not on the very top. It is so called because it sits on the "shoulder" of the fuselage, rather than on the pilot's shoulder. Shoulder-wings and high-wings share some characteristics, namely: they support a pendulous fuselage which requires no wing dihedral for stability; and, by comparison with a low-wing, a shoulder-wing's limited ground effect reduces float on landing. Compared to a low-wing, shoulder-wing and high-wing configurations give increased propeller clearance on multi-engined aircraft.

On a large aircraft, there is little practical difference between a shoulder wing and a high wing; but on light aircraft the configuration is significant because it offers superior visibility to the pilot. On a light aircraft, the shoulder-wing may need to be swept forward to maintain correct center of gravity.[6] Examples of light aircraft with shoulder wings include the ARV Super2, the Bölkow Junior and the Saab Safari.

High wing

High wing on a de Havilland Canada Dash 8.

A high wing has its upper surface on or above the top of the fuselage. It shares many advantages and disadvantages with the shoulder wing, but on a light aircraft the high wing has poorer upwards visibility. On light aircraft such as the Cessna 152, the wing is usually located on top of the pilot's cabin, so that the centre of lift broadly coincides[7] with the centre of gravity.[8]

Parasol wing

Parasol wing on a Pietenpol Air Camper.

A parasol wing aircraft is essentially a biplane without the lower pair of wings. The parasol wing is not directly attached to the fuselage, but is held above it, supported either by cabane struts or by a single pylon.[9] Additional bracing may be provided by struts extending from the fuselage sides. Some early gliders had an open cockpit and a parasol wing mounted on a pylon.

The parasol wing was popular only during the inter-war transition years between biplanes and monoplanes. Compared to a biplane, a parasol wing has less bracing and lower drag; but compared to a high wing, there is so much extra drag that the parasol wing has become obsolete for production aircraft, although it remains a popular configuration for homebuilt aircraft, such as the Pietenpol Air Camper.

References

Citations

  1. http://aviation.stackexchange.com/questions/12143/why-are-there-no-longer-any-biplanes
  2. King, Windkiller, p. 227.
  3. "ch4-3". nasa.gov. Retrieved 16 January 2016.
  4. "Ground Effect in Aircraft". Aviation-history.com. 2009-11-30. Retrieved 2012-07-19.
  5. "Ground Effect". Avweb.com. 2003-10-22. Retrieved 2012-07-19.
  6. Pilot magazine February 1986 page 32
  7. Rarely an exact coincidence: most high-wing aircraft have the centre of lift just aft of the GG, to provide a nose-down moment (that can be countered by tailplane downforce).
  8. Trevor Thom - The Aeroplane (Technical) - 1997 page 65
  9. Crane, Dale: Dictionary of Aeronautical Terms, third edition, page 379. Aviation Supplies & Academics, 1997. ISBN 1-56027-287-2

Bibliography

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