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  • This episode of Real Engineering is brought to you by Curiosity Steam. Sign up today and

  • get free access to my new Logistics of D-Day series on watchnebula.com.

  • Plane wings come in a huge variety of shapes, sizes and configurations. We have explored

  • how the aft swept wings of a traditional airliner and the forward swept wings of experimental

  • planes like the x-29 affect the aerodynamic properties of the plane. We explained why

  • modern day jet fighters are designed to be aerodynamically unstable, and in one of my

  • very first videos we investigated why airliner manufacturers like Boeing and Airbus are installing

  • increasingly complicated winglets at the tips of their wings. However we have never explored

  • in detail the theory and practice behind wing dihedral angles. Which is simply the angle

  • the wings make with respect a perfectly horizontal lie through the base of the wing, and planes

  • throughout history have had a huge variety of variations with this feature.

  • From the high mounted anhedral wing of the AV-8B Harrier, where the wing angles downwards,

  • to the low mounted dihedral wings of airliners and WW2 era fighters and everything in between

  • like modern day F-16s with low mounted straight wings or stranger still the gullwings of seaplanes

  • and inverted gullwing of the F4U Corsair.

  • So what's the purpose behind all these designs? To understand this, we first have to understand

  • the dynamic lift generated by a wing as it rolls.

  • Let's examine a plane with dihedral wings, meaning they point upwards. In straight and

  • left flight the lift each wing generates does not point directly up. As the lift a wing

  • generates is perpendicular to the aerofoil of the wing. This means the lift of wings

  • points inwards at an angle towards the fuselage. [1]

  • This seems like a strange design choice, as only the vertical component of lift contributes

  • to getting the plane off the ground, and thus the horizontal component is wasted energy

  • which results in additional fuel being wasted. So why do they do it? By tilting the wings

  • upwards we gain roll stability, which we explored briefly in myWhy Jet Fighters Can Be Too

  • Unstablevideo. This means that when the plane rolls it will naturally correct itself

  • and return to straight and level flight with no input from the pilot. An important safety

  • feature

  • This works as a result of a planes tendency to side slip when it rolls. Meaning the plane

  • begins to move sideways and downwards in the direction of the bank. This introduces a new

  • air flow to the wing which has both a vertical and sidewise component. As a result of the

  • dihedral angle, this flow strikes the underside of the lower wing with a great angle of attack

  • that the higher wing, and thus the lower wing now generates more lift than the upper wing,

  • providing a restoring force to return the plane to straight and level flight.

  • The exact opposite occurs with anhedral wings, where the wings point downwards. Here when

  • sideslip occurs the upper wing achieves more lift due to a greater angle of attack, causing

  • the plane to roll more.

  • High mounted wings tend to be anhedral. Some sources will tell you that this due to the

  • pendulum effect where the weight of the plane itself acts as a restoring force, like how

  • a pendulum will naturally return to its original position when disturbed, but this is incorrect

  • and I nearly uploaded this explanation on Saturday before thinking about it a little

  • harder and realising that that didn't make any sense.

  • The actual reason high mounted wings are roll stable is a result of how the airflow flows

  • around the fuselage in sideslip. With high mounted wings it will be deflected into the

  • underside of the wing, increasing lift on the lower wing and thus providing a restoring

  • moment, while a low mount wing will have the airflow deflected into the top of the wing

  • providing a moment which will increase the roll.

  • So plane designers will use dihedral wings on low mounted wings to counteract the instability

  • of low mounted wings and use anhedral wings to offset the stability of high mounted wings.

  • We can see examples of anhedral wings in planes like AV-8B Harrier, where the designers needed

  • to use a high mounted wing in order to utilize the direct thrust nozzles that would otherwise

  • strike the top of the wing in a low mounted wing. Perhaps the most impressive example

  • of high mounted anhedral wings is with the Antonov AN-225. The largest plane in the world.

  • I could not find a reference to back this up, but I assume they chose this wing configuration

  • to increase ground clearance for it's 6 turbofan engines, and thus allow the plane

  • to have extremely short landing gear. Which would reduce the material needed for them,

  • and make loading procedures much easier. We also see examples of low mounted wings

  • with no dihedral angle at all, like the F-16. This made the F-16 slightly unstable in roll,

  • allowing for better maneuverability. The F-16 was infact one of the first planes in existance

  • to deliberately introduce instability for the benefit of energy efficient maneuvering.

  • A technology made possible by fly by wire computers.

  • Angling the wings like this does come with disadvantages. One of them is its effect on

  • fuel economy. As stated earlier, only the vertical component of lift contributes to

  • getting the plane off the ground, and thus the horizontal component is wasted energy

  • which results in additional fuel being used, but the effect is tiny if we keep the dihedral

  • angle relatively small. The loss in vertical lift is proportional to the cosine of the

  • dihedral angle. A wing with a dihedral angle of six degrees, like a Boeing 737, will lose

  • just 0.55 percent of it's vertical lift in exchange for roll stability. (Cos (0) - Cos

  • (6) = 0.005478)[2] [3]

  • The configurations mentioned above are the most common, but there are configurations

  • that appear in special circumstances. The F4 Phantom, a fighter created before fly by

  • wire technology was mainstream, was found to be unstable during the testing phase and

  • thus they retrofitted a dihedral angle to the wing tips late in the development stage

  • to increase roll stability. This is called cranked dihedral.

  • One of my favourite planes. The F4U Corsair features inverted gullwings where the wings

  • initially protrude out with an anhedral angle before sweeping back to dihedral. This wasn't

  • for any fancy aerodynamic reason, but for a similar reason to our AN-255.

  • When the F4U Corsair was being designed the engineers had some design criteria they had

  • to hit, namely it was required to be capable of achieving a top speed of 640 kilometres

  • per hour. [4] This would require not only a large engine to achieve the power needed

  • to overcome the immense drag at this speed, but a large propeller to provide thrust. This

  • created ground clearance issues for the plane that would require longer landing gear, but

  • a longer landing gear would need to be stronger, heavier and would take up more space. Instead

  • the designers decided to bring the landing gear closer to the ground by curve the wing

  • downwards where it was located.

  • The gullwings of seaplanes again use them for clearance reasons, as they try to lift

  • the wing mounted engines clear of damaging sea water spray.

  • These are just some examples of how dihedral angles change for different design criteria,

  • but from here you should be able to look at any plane and understand why it chose a particular

  • wing dihedral or anhedral angle. Like the Junkers JU-87 another inverted gull-wing world

  • war 2 era plane flown extensively by the German's. I will be exploring many of these planes and

  • other less examined factors that influenced the outcome of World War 2, in my new Logistics

  • of D-Day series available exclusively on Nebula. The streaming service, my creator friends

  • and I made to provide a new place to upload our content free from the shackles of the

  • YouTube algorithm.

  • In my debut episode I explore the reasons Normandy was chosen as the final landing location,

  • factoring in everything from Allied fighter plane ranges to the geology of Normandy. It's

  • a fascinating topic that you can learn more about for just 2.99 by signing up to CuriosityStream,

  • who are bundling our streaming service with every sign up that uses the link in the description.

  • With this you will get access to the thousands of fantastic documentaries on CuriosityStream,

  • like this one titled Pioneers in Aviation, but also get access to all my new videos completely

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  • As always, thanks for watching and thank you to all my Patreon supporters. If you would

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  • below.

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Why Does Wing Dihedral Make Planes Stable?

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    joey joey に公開 2021 年 06 月 01 日
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