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A cyclist bends so as to increase frictional force which produces enough centripetal force to enable him/her to remain a circular path(since a corner is a part of a circular path). Note:Frictional force produces centripetal force in this case
All objects in motion want to travel in a straight line. to get the object to curve in any direction requires a force or pressure to pull or push it around the curve. A string on a rock gravity on a basketball bullet planet or satellite and in this case friction between the tire and the ground. If the rider tried to stay upright he would tip over. This turning force is called "centrifugal force" and when you add it to gravity the direction of up and down change, just like a rock on a string always hangs straight down but as you swing it in a circle faster and faster it swings outward so its "up" looks slanted to us.
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The application are any time you want something to move in a path that's not straight, you need centripetal force to make it curve away from moving straight. Like if you want to drive your car around a curve or turn a corner.
As the cyclist increases its speed, so too does the frictional force. The cyclist will keep accelerating until both the forces become balanced. The cyclist will then remain at a constant speed until one of the forces changes again. Hope this helps
to counter centrifugal force and to take turn faster
A cyclist bends so as to increase frictional force which produces enough centripetal force to enable him/her to remain a circular path(since a corner is a part of a circular path). Note:Frictional force produces centripetal force in this case
All objects in motion want to travel in a straight line. to get the object to curve in any direction requires a force or pressure to pull or push it around the curve. A string on a rock gravity on a basketball bullet planet or satellite and in this case friction between the tire and the ground. If the rider tried to stay upright he would tip over. This turning force is called "centrifugal force" and when you add it to gravity the direction of up and down change, just like a rock on a string always hangs straight down but as you swing it in a circle faster and faster it swings outward so its "up" looks slanted to us.
hjkhjgjj
Velocity
yes
Friction
inertia, centrifugal force
WORK
It lowers the air resistance, which lets them go faster.
The application are any time you want something to move in a path that's not straight, you need centripetal force to make it curve away from moving straight. Like if you want to drive your car around a curve or turn a corner.
As the cyclist increases its speed, so too does the frictional force. The cyclist will keep accelerating until both the forces become balanced. The cyclist will then remain at a constant speed until one of the forces changes again. Hope this helps