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If a car takes a banked curve at less than the ideal speed, friction is needed to keep it from sliding toward the inside of the curve (a real problem on icy mountain roads).

(a)

Calculate the ideal speed in (m/s) to take an 85 m radius curve banked at 15°.

(b) m/s

What is the minimum coefficient of friction needed for a frightened driver to take the same curve at 20.0 km/h?

User UnholyRanger
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1 Answer

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19 votes

Hello!

a)
For a car on an incline, we only have the normal force and force of gravity acting on the car.

The car is only experiencing a net force caused by the sine component of the force of gravity vector, which causes it to slide down the incline towards the center of the curve.

Or, as an equation:


F_(net) = Mgsin\phi

This net force produces a centripetal force. Recall the equation for centripetal force:

F_c = (mv^2)/(r)

In reference to the 15° angle of the incline, the cosine component of the centripetal force is equivalent to the sine component of the force due to gravity (both parallel to the incline). So:

F_c cos\phi = Mgsin\phi \\\\(mv^2)/(r)cos\phi = mgsin\phi

Cancel out 'm' and solve for 'v'.


(v^2)/(r)cos\phi = gsin\phi\\\\v^2 = gr (sin\phi)/(cos\phi)\\\\v = √(grtan\phi)

Plug in the given values and solve.


v = √((9.8)(85)tan(15)) = \boxed{14.94 (m)/(s)}

b)
Begin by converting 20.0 km/h to m/s.


(20 km)/(hr) * (1 hr)/(3600 s) * (1000m)/(1 km) = 5.556 (m)/(s)

For this situation, we also have the force of friction present along the axis of the sine component of the force of gravity that contributes to the net force.

Recall the equation of kinetic friction:

F_f = \mu_k N

In this situation, we have the sine (vertical) component of the centripetal force as well as the cosine component of the force of gravity making up the normal force, so:

F_f = \mu_k ((mv^2)/(r)sin\phi + mgcos\phi)

If a curve is banked at a slower speed than appropriate, the car will tend to slide towards the center. Thus, this force of friction points up the incline, opposite to the force due to gravity. We can do another summation of forces like above.


(mv^2)/(r) cos\phi= mgsin\phi - \mu_k ((mv^2)/(r)sin\phi + mgcos\phi)

Cancel out 'm' and simplify the equation further to solve for μ.


(v^2)/(r) cos\phi= gsin\phi - \mu_k ((v^2)/(r)sin\phi + gcos\phi)\\\\\mu_k ((v^2)/(r)sin\phi + gcos\phi)= gsin\phi - (v^2)/(r) cos\phi\\\\\mu_k = (gsin\phi - (v^2)/(r) cos\phi)/(((v^2)/(r)sin\phi + gcos\phi))

Plug in values.


\mu_k = (9.8sin(15) - (5.556^2)/(85) cos(15))/((5.556^2)/(85)sin(15) + 9.8cos(15)) = \boxed{0.2286}

If a car takes a banked curve at less than the ideal speed, friction is needed to-example-1
User Michal Holub
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