Qstnid -Iv-29-a Car Moving At A Speed Of 36 Km/hr Is Taking A Turn On A Circular Road Of Radius 50 M. A Small Wooden Plate Is Kept On The Seat With Its Plane Perpendicular To The Radius Of The Circular Road. A Small Block Of Mass 100 G Is Kept On The Seat Which Rests Against The Plate. The Friction Coefficient Between The Block And The Plate Is . (A) Find The Normal Contact Force Exerted By The Plate On The Block. (B) The Plate Is Slowly Turned So That The Angle Between The Normal To The Plate And The Radius Of The Road Slowly Increases. Find The Angle At Which The Block Will Just Start Sliding On The Plate. <Span Style="background-color: #Ffff00;">figure</span></span> - 07: Circular Motion

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NEET-XII-Physics

07: Circular Motion

with Solutions - page 5

Qstn# iv-29 Prvs-Qstn Next-Qstn

#29
A car moving at a speed of 36 km/hr is taking a turn on a circular road of radius 50 m. A small wooden plate is kept on the seat with its plane perpendicular to the radius of the circular road. A small block of mass 100 g is kept on the seat which rests against the plate. the friction coefficient between the block and the plate is . (a) Find the normal contact force exerted by the plate on the block. (b) The plate is slowly turned so that the angle between the normal to the plate and the radius of the road slowly increases. Find the angle at which the block will just start sliding on the plate.
Figure
Ans : Given:
Speed of the car = v = 36 km/h = 10 m/s
Radius of the road = r = 50 m
Friction coefficient between the block and the plate = μ = 0.58
Mass of the small body = m = 100 g = 0.1 kg (a) Let us find the normal contact force (N) exerted by the plant of the block.
`` \,\mathrm{\,N \,}=\frac{m{v}^{2}}{r}=0.1\times \frac{100}{50}=\frac{1}{5}=0.2`` (b) The plate is turned; so, the angle between the normal to the plate and the radius of the rod slowly increases.
Therefore, we have:
`` \,\mathrm{\,N \,}=\frac{m{v}^{2}}{r}\,\mathrm{\,cos\theta \,}...\left(\,\mathrm{\,i \,}\right)``
`` \mu \,\mathrm{\,N \,}=\frac{m{v}^{2}}{r}\,\mathrm{\,sin\theta \,}...\left(ii\right)``
`` \,\mathrm{\,On \,}\,\mathrm{\,using \,}\left(\,\mathrm{\,i \,}\right)\,\mathrm{\,and \,}\left(\,\mathrm{\,ii \,}\right),\,\mathrm{\,we \,}\,\mathrm{\,get \,}:``
`` \frac{\mu m{v}^{2}}{r}\,\mathrm{\,cos \,}\theta =\frac{m{v}^{2}}{r}\,\mathrm{\,sin \,}\theta ``
`` \Rightarrow \,\mathrm{\,\mu \,}=\,\mathrm{\,tan\theta \,}``
`` \Rightarrow \,\mathrm{\,\theta \,}={\,\mathrm{\,tan \,}}^{-1}(0.58)\approx 30°``
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#29-a
Find the normal contact force exerted by the plate on the block.
Ans : Let us find the normal contact force (N) exerted by the plant of the block.
`` \,\mathrm{\,N \,}=\frac{m{v}^{2}}{r}=0.1\times \frac{100}{50}=\frac{1}{5}=0.2``

#29-b
The plate is slowly turned so that the angle between the normal to the plate and the radius of the road slowly increases. Find the angle at which the block will just start sliding on the plate.
Figure
Ans : The plate is turned; so, the angle between the normal to the plate and the radius of the rod slowly increases.
Therefore, we have:
`` \,\mathrm{\,N \,}=\frac{m{v}^{2}}{r}\,\mathrm{\,cos\theta \,}...\left(\,\mathrm{\,i \,}\right)``
`` \mu \,\mathrm{\,N \,}=\frac{m{v}^{2}}{r}\,\mathrm{\,sin\theta \,}...\left(ii\right)``
`` \,\mathrm{\,On \,}\,\mathrm{\,using \,}\left(\,\mathrm{\,i \,}\right)\,\mathrm{\,and \,}\left(\,\mathrm{\,ii \,}\right),\,\mathrm{\,we \,}\,\mathrm{\,get \,}:``
`` \frac{\mu m{v}^{2}}{r}\,\mathrm{\,cos \,}\theta =\frac{m{v}^{2}}{r}\,\mathrm{\,sin \,}\theta ``
`` \Rightarrow \,\mathrm{\,\mu \,}=\,\mathrm{\,tan\theta \,}``
`` \Rightarrow \,\mathrm{\,\theta \,}={\,\mathrm{\,tan \,}}^{-1}(0.58)\approx 30°``
Page No 116: