If you look at the shape of a Frisbee strait on it has the same shape as an airplane wing. It works on the same principle.
Large frisbee=better lift; stays in the air longer small frisbee=drops sooner, is faster Heavy frisbee=drops sooner, better accuracy light frisbee=drops later, may get blown off course by the wind
A ball will bounce if the material it is made of has a high elasticity property. That is the property to return to its original shape when deformed. So when a falling ball hits a hard surface the force of the impact will slightly flatten the ball. This is deforming the ball and when the ball snaps back to its original shape there will be forces on the ball by the surface it is in contact with to push the ball back up.
Lift is generated by the wings to counteract gravity and keep the aircraft airborne. Thrust is provided by the engines to overcome drag, which is the force that resists the aircraft's forward motion. Together, lift and thrust work against gravity and drag to keep the aircraft in a state of controlled flight.
Gravity is the force that pulls an aircraft towards the ground, acting against the force of lift generated by the wings in level flight. Gravity pulls the aircraft downward, while lift generated by the wings counteracts this force to keep the aircraft aloft.
Lift balances weight. Thrust balances drag.
The ridges running around a Frisbee are called "ribs" or "rings." These features help provide stability and lift during flight by creating a more aerodynamic shape. They also improve grip and control when throwing the Frisbee.
Large frisbee=better lift; stays in the air longer small frisbee=drops sooner, is faster Heavy frisbee=drops sooner, better accuracy light frisbee=drops later, may get blown off course by the wind
Paper.
It provides lift to keep the plane airborne.
there is no lift in vertical flight, it is all thrust.
A frisbee flies further when rotating due to the stabilization provided by its spin, which creates gyroscopic stability. This spin helps maintain its orientation in the air, reducing the effects of aerodynamic drag and allowing it to cut through the air more efficiently. Additionally, the rotation generates lift by creating differences in air pressure above and below the disc, enhancing its flight distance. Overall, the combination of stability and lift from rotation contributes significantly to a frisbee's performance in the air.
A ball will bounce if the material it is made of has a high elasticity property. That is the property to return to its original shape when deformed. So when a falling ball hits a hard surface the force of the impact will slightly flatten the ball. This is deforming the ball and when the ball snaps back to its original shape there will be forces on the ball by the surface it is in contact with to push the ball back up.
The frisbee needs to generate lift on the exterior edge of the surface (like an aircarft wing). A sheet of paper is not a frisbee, but a sheet of paper with the shape of a wing all the way around it would be.
The shape of a Frisbee is a disc, with an airfoil cross-section. As with aeroplanes, this airfoil shape generates lift as it moves through the air.
A bald eagle can lift up to 4 pounds in flight.
Lift is generated by the wings to counteract gravity and keep the aircraft airborne. Thrust is provided by the engines to overcome drag, which is the force that resists the aircraft's forward motion. Together, lift and thrust work against gravity and drag to keep the aircraft in a state of controlled flight.
The Frisbee was made to be thrown. In Ultimate, if you do not throw the disc, then you cannot score, and nobody would ever have fun. Since throwing is the only way to advance the disc, this is what you have to do, making it the msot important aspect of Frisbee.