A turn of radius $20 m$ is banked for vehicles going at a speed of $36 km/h$ . If the coefficient of friction between the road and the tyres is $0.4$ , what are the possible speeds of a vehicle so that it neither slips down nor skids up ?

v_{m i n} = 4 m/s; v_{m a x} = 10 m/s

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v_{m i n} = 8 m/s; v_{m a x} = 12 m/s

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v_{m i n} = 6 m/s; v_{m a x} = 10 m/s

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v_{m i n} = 4 m/s; v_{m a x} = 15 m/s

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Solution

The correct option is D $v_{m i n} = 4 m/s; v_{m a x} = 15 m/s$
Angle of banking for design speed is given by
$tan θ = \frac{v_{0}^{2}}{R g}$
Given $v_{0} = 36 km/h = 10 m/s$ and
$R = 20 m$
$\Rightarrow tan θ = \frac{v_{0}^{2}}{R g} = \frac{10^{2}}{20 \times 10} = 0.5$

For speed greater than design speed: The vehicle has a tendency to slide up. Hence, friction will act downward. Since we are looking for maximum speed without skidding, friction will be limiting i.e $f = μ N$

In vertical direction :
$\sum F_{y} = N cos θ - μ N sin θ = m g - (1)$
In horizontal direction :
$\sum F_{x} = \frac{m v_{m a x}^{2}}{R}$
$\Rightarrow N sin θ + μ N cos θ = \frac{m v_{m a x}^{2}}{R} - (2)$
Dividing (2) by (1),
$\frac{N sin θ + μ N cos θ}{N cos θ - μ N sin θ} = \frac{\frac{m v_{m a x}^{2}}{R}}{m g}$
$\Rightarrow \frac{sin θ + μ cos θ}{cos θ - μ sin θ} = \frac{v_{m a x}^{2}}{R g}$
$\Rightarrow \frac{tan θ + μ}{1 - μ tan θ} = \frac{v_{m a x}^{2}}{R g} = \frac{0.5 + 0.4}{1 - 0.4 \times 0.5}$
$\Rightarrow v_{m a x} = 15 m/s$

For speed less than design speed : The vehicle has a tendency to slide down. Hence, friction will act upward. Again, friction will be limiting when speed is minimum (for no slipping)

In horizontal direction:
$\sum F_{t} = \frac{m v_{m i n}^{2}}{R}$
$\Rightarrow N^{'} sin θ - μ N^{'} cos θ = \frac{m v_{m i n}^{2}}{R} - (3)$
In vertical direction:
$N^{'} cos θ + μ N^{'} sin θ = m g - (4)$
Dividing (4) by (3)
$\frac{sin θ - μ cos θ}{cos θ + μ sin θ} = \frac{v_{m i n}^{2}}{R g}$
$\Rightarrow \frac{tan θ - μ}{1 + μ tan θ} = \frac{0.5 - 0.4}{1 + 0.4 \times 0.5} = \frac{v_{m i n}^{2}}{20 \times 10}$
$\Rightarrow v_{m i n} \approx 4 m/s$

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A turn of radius 20 m is banked for vehicles going at a speed of 36 km/h. If the coefficient of friction between the road and the tyres is 0.4, what are the possible speeds of a vehicle so that it neither slips down nor skids up ?

A turn of radius $20 m$ is banked for vehicles going at a speed of $36 km/h$ . If the coefficient of friction between the road and the tyres is $0.4$ , what are the possible speeds of a vehicle so that it neither slips down nor skids up ?