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Forward-swept wing
Forward-swept wing
Forward-swept wing
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Forward-swept wing of the Sukhoi Su-47

A forward-swept wing or reverse-swept wing is an aircraft wing configuration in which the quarter-chord line of the wing has a forward sweep. Typically, the leading edge also sweeps forward. Aircraft with forward-swept are more maneuverable, due to being able to safely sustain higher attack angles. However, they are harder to fly.[1]

Characteristics

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The forward-swept configuration has a number of characteristics which increase as the angle of sweep increases.

Main spar location

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The aft location of the main wing spar would lead to a more efficient interior arrangement with more usable space.

Inward spanwise flow

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Spanwise airflow over a forward-swept wing is the reverse of flow over a conventional swept wing.

Air flowing over any swept wing tends to move spanwise towards the aftmost end of the wing. On a rearward-swept wing this is outwards towards the tip, while on a forward-swept wing it is inwards towards the root. As a result, the dangerous tip stall condition of a rearward-swept design becomes a safer and more controllable root stall on a forward-swept design. This allows full aileron control despite loss of lift, and also means that drag-inducing leading edge slots or other devices are not required. At transonic speeds, shockwaves build up first at the root rather than the tip, again helping ensure effective aileron control.

With the air flowing inwards, wingtip vortices and the accompanying drag are reduced. Instead, the fuselage acts as a very large wing fence and, since wings are generally larger at the root, this raises the maximum lift coefficient allowing a smaller wing. As a result, maneuverability is improved, especially at high angles of attack.

Yaw instability

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One problem with the forward-swept design is that when a swept wing yaws sideways (moves about its vertical axis), one wing retreats while the other advances. With backward-swept wings, this leads to Dutch roll, which is an unpleasant but ultimately stable flight condition. On a forward-swept design, this reduces the sweep of the rearward wing, increasing its drag and pushing it further back, further increasing the amount of yaw and leading to directional instability.[2]

Aeroelasticity

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One of the drawbacks of forward swept wings is the increased chance of divergence, an aeroelastic consequence of the lift force on forward swept wings twisting the tip upwards under increased lift.[3] On a forward-swept design, this causes a positive feedback loop that increases the angle of incidence at the tip, increasing lift and inducing further deflection, resulting in yet more lift and additional changes in wing shape. The effect of divergence increases with speed. The maximum safe speed below which this does not happen is the divergence speed of the aircraft.

Such an increase in tip lift under load causes the wing to tighten into turns and may result in a spiral dive from which recovery is not possible. In the worst case, the wing structure can be stressed to the point of failure.[3]

At large angles of sweep and high speeds, in order to build a structure stiff enough to resist deforming yet light enough to be practicable, advanced materials such as carbon fiber composites are required. Composites also allow aeroelastic tailoring by aligning fibers to influence the nature of deformation to a more favorable shape, impacting stall and other characteristics.[3]

Stall characteristics

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Any swept wing tends to be unstable in the stall, since the wing tips stalls first causing a pitch-up force worsening the stall and making recovery difficult. This effect is less significant with forward sweep because the rearward end carries greater lift and provides stability.

However, if the aeroelastic bending is sufficient, it can counteract this tendency by increasing the angle of attack at the wing tips to such an extent that the tips stall first and one of the main characteristics of the design is lost, on a conventional wing the tips always stall first. Such a tip stall can be unpredictable, especially where one tip stalls before the other.

Composite materials allow aeroelastic tailoring, so that as the wing approaches the stall it twists as it bends, so as to reduce the angle of attack at the tips. This ensures that the stall occurs at the wing root, making it more predictable and allowing the ailerons to retain full control.

History

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Pre-WWII studies

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Viktor Belyaev tested forward-swept wing gliders BP-2 and BP-3 in 1934 and 1935.[4][5] Other prewar design studies included the Polish PWS Z-17, Z-18 and Z-47 "Sęp" series.

World War II and aftermath

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Forward-swept wings designs, some whose design had begun during the prewar period, were developed during World War II, independently in Germany, the Soviet Union, Japan, and the United States. An early example to fly, in 1940, was the Soviet Belyayev DB-LK, a twin-boom design with forward-swept outer wing sections and backwards-swept tips. It reportedly flew well. Belyayev's proposed Babochka research aircraft was cancelled following the German invasion.

Throughout World War II, numerous fighter, bomber, and other military aircraft can be described as having forward-swept wings, due to the average chord of their wings being forward-sweeping. However, these designs almost always utilized a rearward-swept leading edge, which would technically render them as high aspect ratio trapezoidal wings.

The American Cornelius Mallard flew on 18 August 1943. The Mallard was powered by a single engine, but it was followed by the Cornelius XFG-1 prototypes, which were flying fuel tanks, unpowered and designed for towing by larger aircraft. These Cornelius designs were unusual for being not only forward swept but also tailless.

A model of the Ju 287 V1

Meanwhile in Germany, Hans Wocke was studying the problems of swept wings at the near-sonic speeds of which the new jet engines were capable. He recognised many of the advantages that forward sweep offered over the backwards-swept designs then being developed, and also understood the implications of aeroelastic bending and yaw instability. His first such design to fly was the Junkers Ju 287, on 16 August 1944. Flight tests on this and later variants confirmed the low-speed advantages but also soon revealed the expected problems, preventing high-speed trials.

Wocke and the incomplete Ju 287 V3 prototype were captured and, in 1946, taken to Moscow where the aircraft was completed and flown the next year as the OKB-1 EF 131. The later OKB-1 EF 140 was essentially the same airframe re-engined with a pair of Mikulin-design Soviet jet engines of greater thrust. In 1948, the Soviet Union created the Tsybin LL-3.[6] The prototype would subsequently have a great impact on the Sukhoi SYB-A, which was completed in 1982.

When the German research reached the United States after the war, a number of proposals were put forward. These included the Convair XB-53 supersonic bomber and forward-swept variants of the North American P-51 Mustang, Bell X-1 rocket plane and Douglas D-558-I. The Bell proposal reached the wind tunnel testing stage, where the problems of aeroelasticity were confirmed. The structural problems confirmed by the Ju 287 series and the Bell X-1 studies proved so severe that the materials available at the time could not make a wing strong and stiff enough without also making it too heavy to be practical. As a result, forward sweep for high-speed designs was abandoned, until many years later when new structural materials would become available.

Post-WWII general aviation

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LET L-13 two-seat glider
ARV Super2

Small amounts of sweep do not cause serious problems and even moderate forward sweep allows a significant aft movement of the main spar attachment point and carry-through structure.

In 1954, Wocke returned to the German Democratic Republic, moving to West Germany shortly afterwards and joining Hamburger Flugzeugbau (HFB) as their chief designer.[2] In Hamburg, Wocke completed work on the HFB 320 Hansa Jet business jet which flew in 1964. The forward sweep enabled the main spar to be moved aft behind the cabin so that the spar did not need to project into the cabin.

Moderate forward sweep has been used for similar reasons in many designs, mainly sailplanes and light aircraft. Many high-wing training gliders with two seats in tandem have slightly forward-swept wings in order to enable the wing root to be located further aft to prevent the wing from obscuring the rear occupant's lateral visibility. Typical examples are the Schleicher ASK 13 and the Let Kunovice LET L-13 Blaník.

Other examples include:

Fast jet

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Grumman X-29 displaying forward-swept wing configuration
KB SAT SR-10 trainer

The large angles of sweep necessary for high-speed flight remained impractical for many years.

In the late 1970s, DARPA began investigating the use of newer composite materials to avoid the problem of reduced divergence speed through aeroelastic tailoring. Fly-by-wire technology allowed for the design to be dynamically unstable and improved maneuverability. Grumman built two X-29 technology demonstrators, first flying in 1984, with forward swept wings and canards. Maneuverable at high angles of attack, the X-29 remained controllable at a 67° angle of attack.[8]

Advances in thrust vectoring technology and a shift in air combat tactics toward medium range missile engagements decreased the relevance of a highly agile fighter aircraft.

In 1997, Sukhoi introduced the Su-47 fighter prototype at the Paris Air Show. It did not enter production, although it underwent a series of flight tests and performed at several air shows.

The KB SAT SR-10 is a prototype Russian single-engine jet trainer aircraft, fitted with forward-swept wings. It first flew in 2015.

In biology

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Large-headed pterosaurs had forward swept wings in order to better balance in flight.[9]

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Forward-swept wing

View on Grokipedia
from Grokipedia
A forward-swept wing (FSW) is an aircraft wing configuration in which the angles forward from the root toward the tips, in contrast to the conventional aft-swept wing where the tips angle rearward. This design leverages unique aerodynamic effects, such as inward spanwise flow that delays at the wingtips and maintains effectiveness during high angles of attack (AoA), potentially improving maneuverability and lift-to-drag ratios. However, FSWs introduce structural challenges like aeroelastic , necessitating advanced composite materials and active control systems to ensure stability. The concept of forward-swept wings dates back to , with early experimental implementations such as the German jet bomber, which first flew in 1944 and featured a forward-swept wing to enhance low-speed performance, and the American Cornelius XFG-1 glider, which first flew in 1944. Postwar developments included the West German business aircraft in 1964, which demonstrated practical applications but highlighted stability issues. Significant advancements occurred in the late 1970s through U.S. programs sponsored by and , culminating in the experimental aircraft, which conducted its maiden flight on December 14, 1984, and completed over 240 test flights by 1991, validating FSW benefits in and high-AoA regimes up to 66 degrees. Aerodynamically, forward-swept wings offer advantages including up to 20% drag reduction at speeds, a steeper lift curve slope, and improved characteristics where the root stalls first, preserving outboard control surfaces. They also promote better potential and integration with canard foreplanes, reducing the need for twist in spanwise load distribution. Despite these benefits, drawbacks persist, such as increased risk of flutter and —addressed in the X-29 via aeroelastic tailoring and digital systems that managed a 35% unstable with a negative 32% static margin—and higher supersonic due to the low leading-edge sweep. Other notable examples include the Russian S-37 Berkut technology demonstrator in the 1990s and the U.S. AGM-129 Advanced , illustrating FSW applications in both manned fighters and unmanned systems. Overall, while FSWs have not entered widespread production due to these complexities, they remain influential in research for high-performance and morphing aircraft designs.

Aerodynamic Characteristics

Spanwise Flow

In forward-swept wings, the unique induces a spanwise directed inward from the wingtips toward the , contrasting with the outward flow observed on conventional aft-swept wings. This inward migration of air occurs because the , angled forward relative to the flight direction, causes the incoming to follow the swept path, accumulating progressively toward the inboard sections. As a result, the flow remains more attached at the tips during high angles of attack, mitigating premature tip stall and preserving effectiveness, though this benefit is explored further in related stall analyses. The aerodynamic principle governing this flow involves the sweep angle θ, where the ratio of the spanwise velocity component to the chordwise component approximates tan(θ), directing the along the wing's sweep. This relationship ensures that the spanwise velocity, proportional to the velocity times sin(θ), drives the inward component, enhancing flow uniformity across the span. In comparison, aft-swept wings experience outward spanwise flow due to the opposite sweep orientation, which leads to tip washout—a reduction in local at the outboard sections from buildup and vortex formation, exacerbating tip stall tendencies. This inward spanwise flow contributes to aerodynamic efficiency by promoting a more distribution over the , which supports a lift distribution closer to the ideal elliptical profile. An elliptical lift distribution minimizes induced drag for a given total lift, as it equalizes and reduces tip vortex strength compared to tapered or less loadings. Studies confirm that forward-swept configurations achieve this beneficial profile more naturally, yielding lower induced drag coefficients at moderate angles of attack relative to aft-swept counterparts with similar planforms.

Stall Behavior

In forward-swept wings, the characteristic inward spanwise flow directs airflow from the tips toward the , causing to initiate at the root section rather than the tips. This root-first progression maintains attached flow over the outboard wing panels, preserving aileron effectiveness and lateral control even as the angle of attack increases. As a result, pilots retain roll authority during the onset of , reducing the risk of loss of control associated with tip in conventional aft-swept designs. This stall behavior provides significant advantages in high-angle-of-attack maneuvers, enabling sustained angles up to approximately 60 degrees without complete loss of control. In the X-29 demonstrator, this characteristic permitted controllable flight up to 67 degrees , with graceful degradation in handling beyond 45 degrees but maintained stability through 55 degrees in limited maneuvers.

Lift Distribution

Forward-swept wings achieve a more uniform spanwise lift distribution compared to conventional aft-swept designs, primarily due to the inward migration of along the span. This flow pattern directs higher-energy air from the tips toward the root, resulting in elevated lift generation near the and reduced lift at the outboard sections. Consequently, the overall loading approximates an ideal elliptical profile, which minimizes the intensity of and thereby reduces induced drag. The lift distribution on forward-swept wings closely mimics the elliptical loading theorized by Prandtl in , where the spanwise lift variation is proportional to 1(2y/b)2\sqrt{1 - (2y/b)^2}
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