For a thin flat plate at a low angle of attack , the lift coefficient Clo is equal to 2.0 times pi (3.14159) times the angle a expressed in radians (180 degrees equals pi radians):
Clo = 2 * pi * a
T.O.E Dream said:Let's say we have a rectangular surface or something. How about a piece of plywood. If we were to blow air say using a fan at the top of the wood and keep the air "calm" at the bottom, would it create lift?
I know it's not practical but in theory should there be a slight lift?
Negative lift or at best no lift. The air just aft of the fan has higher than ambient pressure, and continues to accelerate as it's pressure returns to ambient. Change this so the fan is above and aft of the wood, sucking air instead of blowing it, and the pressure is reduced, which would result in lift.If we were to blow air say using a fan at the top of the wood and keep the air "calm" at the bottom, would it create lift?
That's not what the OP is getting at. He wants to flow high speed air over the top surface while leaving the air at the bottom surface unchanged.Jeff Reid said:Negative lift or at best no lift. The air just aft of the fan has higher than ambient pressure, and continues to accelerate as it's pressure returns to ambient. Change this so the fan is above and aft of the wood, sucking air instead of blowing it, and the pressure is reduced, which would result in lift.
This only works on a cambered airfoil due to coanada like effect or what I call void effect, where following the cambered surface corresponds to reduced pressure and downwards acceleration. If the "wing" was a flat board with no angle of attack, then the higher pressure of the prop wash above the "wing" and the ambient pressure below the "wing" would result in a downwards force on the "wing".Phrak said:In any case, the answer is yes. A stream of air directed over a surface generates low pressure on the surface.
Jeff Reid said:This only works on a cambered airfoil due to coanada like effect or what I call void effect, where following the cambered surface corresponds to reduced pressure and downwards acceleration. If the "wing" was a flat board with no angle of attack, then the higher pressure of the prop wash above the "wing" and the ambient pressure below the "wing" would result in a downwards force on the "wing".
The constricted airstream is an idealized case based on constant mass flow, and occurs regardless of pressure (compression effect reduces this by a tiny amount). If the mass flow is constant (this ignores viscosity effects on the air surrounding the prop wash), then the cross sectional area decreases linearly with an increase in speed, (ignoring the minor compression effect), regardless of the pressure. As noted in the wiki article mentioned above, the prop wash (aft of the propeller) pressure is higher than ambient.Phrak said:Jeff, the prop wash is low pressure air. I suppose you could invoke the Bernolli effect, but notice that the airstream downstream of the propeller is low pressure as evidenced by the constricted airsteam.
A fan creates lift by using its blades to push air downwards. According to Newton's Third Law of Motion, for every action, there is an equal and opposite reaction. So, when the fan blades push the air downwards, the air exerts an equal force on the blades in the opposite direction. This results in a net upward force, creating lift.
The amount of lift created by a fan depends on several factors, including the size and shape of the fan blades, the speed of the fan, and the density of the air. The larger and more angled the blades, the more air they can push and the more lift they can create. A faster fan will also create more lift, and denser air (such as at higher altitudes) will provide more resistance for the blades to push against, resulting in more lift.
The lift created by a fan can be measured by using a force meter or spring scale. Attach the device to the fan and measure the force exerted by the air as it pushes against the blades. This force is the lift created by the fan.
Yes, any type of fan can create lift as long as it has blades that can push air downwards. However, the amount of lift may vary depending on the factors mentioned in question 2.
When conducting an experiment to create lift with a fan, it is important to control and consider additional variables such as the distance between the fan and the object being lifted, the weight of the object, and the angle of the fan blades. These variables can affect the amount of lift created and should be kept consistent for accurate results.