That's Newton's 2nd law applied to circular motion to give you the centripetal force. In this case, what is providing that force? (What is F equal to?) Plug in what you know about F and you'll be able to solve for v.fcb said:F=mv2/r
Thanks for your fast and prompt reply.Astronuc said:What is acting against the centrifugal force?
http://hyperphysics.phy-astr.gsu.edu/hbase/cf.html
http://hyperphysics.phy-astr.gsu.edu/hbase/corf.html#cent
All i know about 'F' is that it is equal to 75% of the cars weight. I don't know the cars mass, How am i able to solve for F? I am lost in my own little world.Doc Al said:That's Newton's 2nd law applied to circular motion to give you the centripetal force. In this case, what is providing that force? (What is F equal to?) Plug in what you know about F and you'll be able to solve for v.
Good!fcb said:All i know about 'F' is that it is equal to 75% of the cars weight.
Call the car's mass 'm'. How would you express F in terms of m?I don't know the cars mass, How am i able to solve for F?
Doc Al said:Good!
Call the car's mass 'm'. How would you express F in terms of m?
Almost. Given the mass, how do you calculate the weight?fcb said:Would it be F=.75 x 'm'
Doc Al said:Almost. Given the mass, how do you calculate the weight?
Right. W = mg, where g = 9.8 m/s^2.fcb said:multiply it by acceleration due to gravity which is 9.8ms-2
Good! That radius will have units of m.fcb said:7.35=400/r
400/7.35 = 54.42
= 54.42
Frictional force on bend is the force that resists the motion of an object along a curved surface or bend due to the contact between the two surfaces.
Frictional force on bend can be calculated using the formula F = μN, where F is the frictional force, μ is the coefficient of friction, and N is the normal force between the two surfaces.
The magnitude of frictional force on bend is affected by the roughness of the two surfaces, the normal force between them, and the coefficient of friction.
Frictional force on bend acts in the opposite direction of an object's motion, causing it to slow down or stop completely if the force is strong enough. It also causes objects to turn or change direction when moving along a curved surface.
Some examples of frictional force on bend include the friction between a car's tires and the road when turning, the friction between a bicycle tire and the pavement when making a turn, and the friction between a skateboard and a ramp when performing a trick.