A wing will generate lift according to the following equation:
L = ½ A C ρ v²
A = wing area
C = lift coefficient
ρ = air density
v = air speed
From the equation you can see that the lift force is directly proportional to the wing area. Double the wing area and you double the lift, all else remaining equal.
A plane with large wings is likely to have more lift because the airflow around the plane is more.AnswerThe amount of Lift produced by a wing depends on several variables: Wing size(plan shape), Airfoil shape and Angle of Attack.Wings are designed with different airfoil shape. So a large wing will not have the same airfoil shape as a smaller wing for the same aircraft weight. Like wise, the wing can be designed to have a fixed angle of attack that is more on one aircraft than another.
Lift pushes the airplane up. The way air moves around the wings gives the airplane lift. The shape of the wings helps with lift, too.
If one of the wings are longer , then the longer of the two wings will produce more lift due the increase in surface area .
There is a reason birds fly and pigs do not. Birds have hollow bones and are light. The lift of the wings can support their light weight. Pigs have heavy bones and do not have the strength to either jump or lift in their appendages to support their weight. In airplanes, a heavy airplane, C130, must have more lift in the wings than a light airplane.
The airpresureunder the wings is greaterthan the pressure over the wings creating lift.
The large one on a birds wings; they produce lift.
because they have little wings and a large body that they can not lift
Long wings create more lift. So jet planes have long wings.
A wing is just a large sail lying on its side. The larger the sail's surface area, the greater the wind effect or lift.
A plane with large wings is likely to have more lift because the airflow around the plane is more.AnswerThe amount of Lift produced by a wing depends on several variables: Wing size(plan shape), Airfoil shape and Angle of Attack.Wings are designed with different airfoil shape. So a large wing will not have the same airfoil shape as a smaller wing for the same aircraft weight. Like wise, the wing can be designed to have a fixed angle of attack that is more on one aircraft than another.
Owls have large wings to improve lift and help in gliding. Speed is a product of thrust or gravity (altitude change). Think evolution gave them large wings so they can glide efficiently to the prey without making noise by flapping their wings.
Large wings with proper aerodynamic design create more lift requiring less speed. Or more weight carrying ability. basicly small wings plus light load plus big engine eqauls hi speed, big wings big engine eqauls big load carrying ability, big wings plus small engine eqauls slow plane.
Lift! The wings on a plane create an upward lift.
A device to aid lift, such as Slats and Flaps on the wings.
Research shows that for a stunt paper airplane, smaller wings with forward-concentrated weight are optimal. For a glider, make a large wingspan and light, evenly balanced weight. Also, the wider the wings are the easier it will be to gain lift and the more narrower the wings are the harder it will be to stay in the air longer.
With big wings you can get lift with less trust Small wings you would need a lot of trust to keep the lift. How about a happy medium
A bird creates lift by flapping its wings Aircraft move by the air moving over the wings (where as birds move by moving their wings around the air)