3 Marks Question

Question 13 Marks

A sphere is dropped under gravity through a fluid of viscosity $\eta$. Taking the average acceleration as half of the initial acceleration, show that the time taken to attain the terminal velocity is independent of the fluid density.

Answer

Suppose a sphere of radius r and density $\rho$ falls in a fluid of density $\rho^{\prime} p ^{\prime}$ and viscosity $\eta$. When the sphere just enters the fluid, the net downward force on it is
$F =$ Weight of the sphere - Weight of the fluid displaced
$
=\frac{4}{3} \pi r^3 \rho g-\frac{4}{3} \pi r^3 \rho^{\prime} g=\frac{4}{3} \pi r^3\left(\rho-\rho^{\prime}\right) g
$
It is Given that, average acceleration as half of the initial acceleration.
$\therefore$ Initial acceleration,
$
a=\frac{F}{m}=\frac{\frac{4}{3} \pi r^3\left(\rho-\rho^{\prime}\right) g}{\frac{4}{3} \pi r^3 \rho}=\left(\frac{\rho-\rho^{\prime}}{\rho}\right) g
$
When the sphere attains terminal velocity, its acceleration becomes zero.
$\therefore$ Average acceleration $=\frac{a+0}{2}=\left(\frac{\rho-\rho^{\prime}}{2 \rho}\right) g$
Let the sphere take time $t$ to attain the terminal velocity,
$
v=\frac{2}{9} \frac{r^2}{\eta}\left(\rho-\rho^{\prime}\right) g
$
Initial velocity, $u =0$
Hence by using first equation of motion
$
\begin{aligned}
& v=u+at \\
& \frac{2}{9} \frac{r^2}{\eta}\left(\rho-\rho^{\prime}\right) g=0+\left(\frac{\rho-\rho^{\prime}}{2 \rho}\right) g t \\
& \text { or } t=\frac{4}{9} \cdot \frac{r^2 \rho}{\eta}
\end{aligned}
$

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Question 23 Marks

Show that a liquid at rest exerts a force perpendicular to the surface of the container at every point.

Answer

Consider a liquid contained in a vessel in the equilibrium state of rest. As shown in Fig., suppose the liquid exerts a force F on the bottom surface in an inclined direction OA. The surface exerts an equal reaction R to water along OB.

The reaction R along OB has two rectangular components:
i. Tangential component, $OC = R \cos \theta$
ii. Normal component, $OD = R \sin \theta$
Since a liquid cannot resist any tangential force, the liquid near O should begin to flow along OC . But the liquid is at rest, the force along OC must be zero.
$
\therefore R \cos \theta=0
$
As $R \neq 0$, so $\cos \theta=0$ or $\theta=90^{\circ}$
Hence a liquid always exerts a force perpendicular to the surface of the container at every point.

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Question 33 Marks

A body of mass 5 kg is acted upon by two perpendicular forces 8 N and 6 N . Give the magnitude and direction of the acceleration of the body.

Answer

Mass of the body, $m=5 kg$
The given situation can be represented as follows:

The resultant of two forces is given as:
$
R=\sqrt{(8)^2+(-6)^2}=\sqrt{64+36}=10 N
$
$\theta$ is the angle made by R with the force of 8 N
$
\therefore \theta=\tan ^{-1}\left(\frac{-6}{8}\right)=-36.87^{\circ}
$
The negative sign indicates clockwise direction, and the force of the magnitude is 8 N,
Using Newton's second law of motion, the acceleration (a) of the body is given as:
$
\begin{aligned}
& F=ma \\
& \therefore a=\frac{F}{m}=\frac{10}{5}=2 m / s^2
\end{aligned}
$
This will be an acceleration in the positive direction, because the applied force acts as a push.

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Question 43 Marks

Specific heat of Argon at constant Pressure is $0.125 cal / g / K$ and at constant volume is $0.075 cal / g / K$. Calculate the density of Argon at N.T.P. Given that $J =4.2$ Joule/cal?

Answer

Specific heat of argon at constant pressure, $C _{ P }=0.125 cal / g / K$
$
\begin{aligned}
& \left.C_{P}=0.125 \times 4.2 \times 1000 J / Kg / K \text { (using } 1 cal=4.2 J\right) \\
& C_{P}=525 J / Kg / K \ldots(i)
\end{aligned}
$
Specific heat of argon at constant volume, $C _{ V }=0.075 cal / g / K$
$
C_V=0.075 \times 4.2 \times 1000=315 J / Kg / K
$
The gas constant, r for 1 kg of gas is given by:-
$
r=C_P-C_V=525-315=210 J / Kg / K
$
$
\begin{aligned}
& \text { Normal pressure }=P=h P g=0.76 \times 13600 \times 9.8=101292.8 N / m^2 \\
& \text { Normal Temperature }=T=273 K .
\end{aligned}
$
$
\begin{aligned}
& \text { Suppose } V=\text { Volume of argon gas at } N \text {. T. P. } \\
& PV=nrT \\
& \text { for } n=1 mole \\
& \frac{P V}{T}=r
\end{aligned}
$
$
\begin{aligned}
& V=\frac{r T}{P}=\frac{210 \times 273}{101292.8}=0.566 m^3 \\
& \rho=\frac{\text { Mass }}{\text { Volume }}=\frac{1}{0.566}=1.8 Kg / m^3
\end{aligned}
$
Hence the density of argon is $1.8 Kg / m ^3$.

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Question 53 Marks

A block of metal of mass 50 g when placed over an inclined plane at an angle of $15^{\circ}$ slides down without acceleration. If the inclination is increased by $15^{\circ}$, what would be the acceleration of the block?

Answer

Here $m =50 g=0.05 kg$
Angle of repose,
$
\begin{aligned}
& \alpha=15^{\circ} \\
& \therefore \mu=\tan \mu=\tan 15^{\circ}=0.2679
\end{aligned}
$
New angle of inclination $=15+15=30^{\circ}$
Let a be the downward acceleration produced in the block.

Net downward force on the block is
$
F=mg \sin \theta-f
$
$\begin{aligned} & ma = mg \sin \theta- u mg \cos \theta[\because f=\mu R=\mu m g \cos \theta] \\ & \therefore \quad a=g(\sin \theta-\mu \cos \theta) \\ & =9.8\left(\sin 30^{\circ}-0.2679 \cos 30^{\circ}\right) \\ & =9.8(0.5-0.2679 \times 0.866) \\ & =9.8 \times 0.2680=2.6 ms^{-2}\end{aligned}$

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Question 63 Marks

Two trains, each having a speed of $30 km / h$, are headed towards each other on the same track. A bird that can fly $60 km / h$ flies off the front of one train when they were 60 km apart and heads directly to the other train. On reaching the train, the bird flies back to the first train. What is the total distance the bird travels before the trains collide?

Answer

Here, it is given that, $v_1=30 km / h , v_2=60 km / h$ and $d =60 km$
Therefore, $v_1=30 km / h =30 \times \frac{5}{18}=8.33 m / s$
and $v_2=60 km / h =60 \times \frac{5}{18}=16.67 m / s$
Also, $d =60 km=60000 m$ (because $1 km=1000 m$ )
Since the trains will collide in the middle, we have
$
\Delta x=30 km
$
When trains collide, $v=\frac{\Delta x}{\Delta t} \Rightarrow \Delta t=\frac{\Delta x}{v}$
$
\therefore \quad \Delta t=\frac{30000}{8.33}=3601
$
Now, $v=\frac{\Delta x}{\Delta t} \Rightarrow \Delta x=v \Delta t$
$
\begin{aligned}
& \therefore \Delta x=(16.67 m / s)(3601) \\
& \approx 60028.67 m \approx 60 km
\end{aligned}
$

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Question 73 Marks

A 10 kW drilling machine is used to drill a bore in a small aluminium block of mass 8.0 kg . How much is the rise in temperature of the block in 2.5 minutes, assuming $50 \%$ of power is used up in heating the machine itself or lost to the surroundings. Specific heat of aluminium $=0.91 J g ^{-1} K^{-1}$.

Answer

Power of the drilling machine, $P =10 kW=10 \times 10^3 W=10^4 W$
Mass of the aluminum block, $m =8.0 kg=8000 g$
Time, $t =2.5 min=2.5 \times 60=150 s$
Specific heat of aluminium, $c =0.91 J g ^{-1} K^{-1}$
Let rise in the temperature of the block after drilling $=\delta T$
Total energy of the drilling machine $=P \times T$
$
=10 \times 10^3 \times 150=1.5 \times 10^6 J
$
As only $50 \%$ of the energy is useful as per the question
so useful energy, $\Delta Q=\frac{50}{100} \times 1.5 \times 10^6=7.5 \times 10^5 J$
But $\Delta Q=m c \Delta T$
$
\begin{aligned}
& \therefore \Delta T=\frac{\Delta Q}{m c} \\
& =\frac{7.5 \times 10^5}{8 \times 10^3 \times 0.91}=103^{\circ} C
\end{aligned}
$
Therefore, temperature of block increases by $103^0 C$ in drilling for 2.5 minutes.

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Question 83 Marks

A metallic sphere of radius $1.0 \times 10^{-3} m$ and density $1.0 \times 10^4 kg m ^{-3}$ enters a tank of water, after a free fall through a distance of $h$ in the earth's gravitational field. If its velocity remains unchanged after entering water, determine the value of $h$. Given coefficient of viscosity of water $=1.0 \times 10^{-3} Nsm ^{-2}, g=10 ms^{-2}$ and density of water $=1.0 \times 10^3 kgm ^{-3}$.

Answer

The velocity attained by the sphere after falling freely from height $h$ is $v =\sqrt{2 g h} \ldots$ (i)
After entering water, the velocity of the sphere does not change. So v is also the terminal velocity of the sphere. Hence $v =\frac{2}{9} \frac{r^2}{\eta}\left(\rho-\rho^{\prime}\right) g$
But $\rho=10^4 kgm ^{-3}, \rho^{\prime}=10^3 kgm ^{-3}, r =10^{-3} m, g =10 ms^{-2}, \eta=10^{-3} Nsm ^{-2}$
$
\therefore v=\frac{2}{9} \times \frac{\left(10^{-3}\right)^2 \times\left(10^4-10^3\right) \times 10}{10^{-3}}=20 ms^{-1}
$
From (i), h $=\frac{v^2}{2 g}=\frac{20 \times 20}{2 \times 10}=20 m$

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Physics 3 Marks Question

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