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HC Verma Questions and Solutions: Chapter 5- Newton's Laws of Motion- 2 | HC Verma Solutions - JEE PDF Download

Exercise 

Q.1. A block of mass 2 kg placed on a long frictionless horizontal table is pulled horizontally by a constant force F. It is found to move 10 m in the first seconds. Find the magnitude of F.

Given:
Mass of the block, m = 2 kg,
Distance covered, S = 10 m and initial velocity, u = 0
Let a be the acceleration of the block.
Using, S = ut + (1/2)at2
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
∴ Force, F = ma = 2 × 5 = 10 N


Q.2. Car moving at 40 km/hr is to be stopped by applying brakes in the next 4 m. If the car weighs 2000 kg, what average force must be applied to stop it?

Given:
Initial speed of the car, u = 40 km/hr
= 4000/3600 = 11.11 m/s
Final speed of the car, v = 0
Mass of the car, m = 2000 kg
Distance to be travelled by the car before coming to rest, s = 4m
Acceleration,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
∴ Average force to be applied to stop the car, F = ma
⇒ F = 2000 × 15.42 ≈ 3.1 × 10N.


Q.3. In a TV picture tube, electrons are ejected from the cathode with negligible speed and they attain a velocity of 5 × 106 m/s in travelling one centimetre. Assuming straight-line motion, find the constant force exerted on the electrons. The mass of an electron is 9.1 × 10−31 kg.

Initial velocity of the electrons is negligible, i.e. u = 0.
Final velocity of the electrons, v = 5 × 106 m/s
Distance travelled by the electrons,
s = 1 cm = 1 × 10−2m

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEESo, force on the electrons, F = ma
⇒ F = 9.1 × 10−31 × 12.5 × 10−14
= 1.1 × 10−15 N


Q.4. A block of mass 0.2 kg is suspended from the ceiling by a light string. A second block of mass 0.3 kg is suspended from the first block by another string. Find the tensions in the two strings. Take g = 10 m/s2.

The free-body diagrams for both the blocks are shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram of the 0.3 kg block,
T = 0.3g
⇒ T= 0.3 × 10 = 3 N
Now, from the free-body diagram of the 0.2 kg block,
T= 0.2g + T
⇒ T1= 0.2 × 10 + 3 = 5 N
∴ The tensions in the two strings are 5 N and 3 N, respectively.


Q.5. Two blocks of equal mass m are tied to each other through a light string. One of the blocks is pulled along the line joining them with a constant force F. Find the tension in the string joining the blocks.

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Let a be the common acceleration of the blocks.
For block 1,
F - T = ma
For block 2,
T = ma    ...(2)
Subtracting equation (2) from (1), we get:
F - 2T = 0
⇒ T = F/2


Q.6. A particle of mass 50 g moves in a straight line. The variation of speed with time is shown in the following figure. Find the force acting on the particle at t = 2, 4 and 6 seconds.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Given:
Mass of the particle, m = 50 g = 5 × 10−2 kg
Slope of the v-t graph gives acceleration.
At t = 2 s,
Slope = 15/3 = 5m/s2
So, acceleration, a = 5 m/s2
F = ma = 5 × 10−2 × 5
⇒ F = 0.25 N along the motion.
At t = 4 s,
Slope = 0
So, acceleration, a = 0
⇒ F = 0
At t = 6 sec,
Slope = (-15)/3 = -5m/s2
So, acceleration, a = − 5 m/s2
F = ma = − 5 × 10−2 × 5
⇒ F =  0.25 N along the motion
or, F = 0.25 N opposite the motion.


Q.7. Two blocks A and B of mass mA and mB , respectively, are kept in contact on a frictionless table. The experimenter pushes block A from behind, so that the blocks accelerate. If block A exerts force F on block B, what is the force exerted by the experimenter on block A?

Let F' = force exerted by the experimenter on block A and F be the force exerted by block A on block B.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Let a be the acceleration produced in the system.
For block A,
F' - F = mAa ...(1)
For block B,
F = mBa    ...(2)              
Dividing equation (1) by (2), we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
∴ Force exerted by the experimenter on block A is
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.8. Raindrops of radius 1 mm and mass 4 mg are falling with a speed of 30 m/s on the head of a bald person. The drops splash on the head and come to rest. Assuming equivalently that the drops cover a distance equal to their radii on the head, estimate the force exerted by each drop on the head.

Given:
Radius of a raindrop, r = 1 mm = 10−3 m
Mass of a raindrop, m = 4 mg = 4 × 10−6 kg
Distance covered by the drop on the head, s = 10−3 m
Initial speed of the drop, v = 0
Final speed of the drop, u = 30 m/s
Using HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE we get:HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Force, F = ma
⇒ F = 4 × 10−6 × 4.5 × 105 = 1.8 N


Q.9. A particle of mass 0.3 kg is subjected to a force F = −kx with k = 15 N/m. What will be its initial acceleration if it is released from a point x = 20 cm?

Displacement of the particle from the mean position, x = 20 cm = 0.2 m
k = 15 N/m
Mass of the particle, m = 0.3 kg

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEESo, the initial acceleration when the particle is released from a point x = 20 cm is 10 m/s2  opposite to the direction of motion.


Q.10. Both the springs shown in the following figure are unstretched. If the block is displaced by a distance x and released, what will be the initial acceleration?
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Let the block m be displaced towards left by displacement x.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE opposite the displacement or towards the mean position. 


Q.11. A small block B is placed on another block A of mass 5 kg and length 20 cm. Initially, the block B is near the right end of block A (In the following Figure). A constant horizontal force of 10 N is applied to the block A. All the surfaces are assumed frictionless. Find the time that elapses before block B separates from A.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Mass of block A, m = 5 kg
F = ma = 10 N
⇒ a = 10/5 = 2m/s2
As there is no friction between A and B, when block A moves, block B remains at rest in its position.

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEEInitial velocity of A, u = 0Distance covered by A to separate out,s = 0.2 mHC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEEHC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Q.12. A man has fallen into a ditch of width d and two of his friends are slowly pulling him out using a light rope and two fixed pulleys as shown in the following figure. Show that the force (assumed equal for both the friends) exerted by each friend on the road increases as the man moves up. Find the force when the man is at a depth h.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

(a) At any depth, let the ropes makes an angle θ with the vertical.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
Fcosθ + Fcosθ − mg = 0
2Fcosθ = mg
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
As the man moves up, θ increases, i.e. cosθ decreases. Thus, F increases.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(b) When the man is at depth h,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.13. The elevator shown in the following figure is descending with an acceleration of 2 m/s2. The mass of the block A is 0.5 kg. What force is exerted by the block A on the block B?
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

When the elevator is descending, a pseudo-force acts on it in the upward direction, as shown in the figure.  
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram of block A,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the force exerted by the block A on the block B is 4 N.


Q.14. A pendulum bob of mass 50 g is suspended from the ceiling of an elevator. Find the tension in the string if the elevator (a) goes up with acceleration 1.2 m/s2, (b) goes up with deceleration 1.2 m/s2, (c) goes up with uniform velocity, (d) goes down with acceleration 1.2 m/s2, (e) goes down with deceleration 1.2 m/s2 and (f) goes down with uniform velocity.

(a) When the elevator goes up with acceleration 1.2 m/s2:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
T = mg + ma
⇒ T = 0.05 (9.8 + 1.2) = 0.55 N
(b) Goes up with deceleration 1.2 m/s2 :
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
T = mg + m(-a) = m(g - a)
⇒ T  = 0.05 (9.8 − 1.2) = 0.43 N
(c) Goes up with uniform velocity:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
T = mg
⇒ T = 0.05 × 9.8 = 0.49 N
(d) Goes down with acceleration 1.2 m/s:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(e) Goes down with deceleration 1.2 m/s2 :
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(f) Goes down with uniform velocity:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
T = mg
⇒ T = 0.05 × 9.8 = 0.49 N


Q.15. A person is standing on a weighing machine placed on the floor of an elevator. The elevator starts going up with some acceleration, moves with uniform velocity for a while and finally decelerates to stop. The maximum and the minimum weights recorded are 72 kg and 60 kg, respectively. Assuming that the magnitudes of acceleration and deceleration are the same, find (a) the true weight of the person and (b) the magnitude of the acceleration. Take g = 9.9 m/s2.

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Maximum weight will be recorded when the elevator accelerates upwards.
Let N be the normal reaction on the person by the weighing machine.
So, from the free-body diagram of the person,
N = mg + ma ...(1)
This is maximum weight, N = 72 × 9.9 N
When decelerating upwards, minimum weight will be recorded.
N' = mg + m(-a) ...(2)
This is minimum weight, N' = 60 × 9.9 N
From equations (1) and (2), we have:
2 mg = 1306.8
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the true mass of the man is 66 kg.
And true weight = 66 × 9.9 = 653.4 N
(b) Using equation (1) to find the acceleration, we get:
mg + ma = 72 × 9.9
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.16. Find the reading of the spring balance shown in the following figure. The elevator is going up with an acceleration g/10, the pulley and the string are light and the pulley is smooth.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Let the left and right blocks be A and B, respectively.
And let the acceleration of the 3 kg mass relative to the elevator be 'a' in the downward direction.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Adding both the equations, we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Putting value of the masses,we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Now, using equation (1), we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
The reading of the spring balance = HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
= 4 . 4 kg


Q.17. A block of 2 kg is suspended from a ceiling by a massless spring of spring constant k = 100 N/m. What is the elongation of the spring? If another 1 kg is added to the block, what would be the further elongation?

Given,
mass of the first block, m = 2 kg
k = 100 N/m
Let elongation in the spring be x.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
kx = mg
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Suppose, further elongation, when the 1 kg block is added, is Δx Then, k(x + Δx) = m'g
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.18. Suppose the ceiling in the previous problem is that of an elevator which is going up with an acceleration of 2.0 m/s2. Find the elongation.

When the ceiling of the elevator is going up with an acceleration 'a', then a pseudo-force acts on the block in the downward direction.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
a = 2 m/s2
From the free-body diagram of the block,
kx = mg + ma
⇒ kx = 2g + 2a
= 2 × 9.8 + 2 × 2
= 19.6 + 4
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
When 1 kg body is added,
total mass = (2 + 1) kg = 3 kg
Let elongation be x'.
∴ kx' = 3g + 3a = 3 × 9.8 + 6
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, further elongation = x' − x
= 0.36 − 0.24 = 0.12 m.


Q.19. The force of buoyancy exerted by the atmosphere on a balloon is B in the upward direction and remains constant. The force of air resistance on the balloon acts opposite the direction of velocity and is proportional to it. The balloon carries a mass M and is found to fall to the earth's surface with a constant velocity v. How much mass should be removed from the balloon so that it may rise with a constant velocity v?

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.20. An empty plastic box of mass m is found to accelerate up at the rate of g/6 when placed deep inside water. How much sand should be put inside the box so that it may accelerate down at the rate of g/6?

Let U be the upward force of water acting on the plastic box.
Let m be the initial mass of the plastic box.
When the empty plastic box is accelerating upward,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Let M be the final mass of the box after putting some sand in it.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Mass added
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From equation (i),
m = 6U/7g
∴ Mass added
= 2/5 m.


Q.21. A force HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE is exerted on a particle in addition to the force of gravity, where HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE  is the velocity of the particle and HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE is a constant vector in the horizontal direction. With what minimum speed, a particle of mass m be projected so that it continues to move without being defelected and with a constant velocity?

For the particle to move without being deflected and with constant velocity, the net force on the particle should be zero.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
v will be minimum when sinθ = 1.
⇒ θ = 90°
∴ vmin = mg/A along Z-axis.


Q.22. In a simple Atwood machine, two unequal masses m1 and m2 are connected by a string going over a clamped light smooth pulley. In a typical arrangement (In the following figure), m1 = 300 g and m= 600 g. The system is released from rest. (a) Find the distance travelled by the first block in the first two seconds; (b) find the tension in the string; (c) find the force exerted by the clamp on the pulley.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

The masses of the blocks are m1 = 0.3 kg and m2 = 0.6 kg
The free-body diagrams of both the masses are shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
For mass m1,
T − m1g = m1a ...(i)
For mass m2,
m2g − T= m2a ...(ii)
Adding equations (i) and (ii), we get:
g(m2 − m1) = a(m1 + m2)
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(a) t = 2 s, a = 3.266 ms−2, u = 0
So, the distance travelled by the body,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(b) From equation (i),
T = m1 (g + a)
= 0.3 (9.8 + 3.26) = 3.9 N
(c)The force exerted by the clamp on the pulley,
F = 2T = 2 × 3.9 = 7.8 N


Q.23. Consider the Atwood machine of the previous problem. The larger mass is stopped for a moment, 2.0 s after the system is set into motion. Find the time that elapses before the string is tight again.

a = 3.26 m/s2, T = 3.9 N
After 2 s, velocity of mass m1,
v = u + at = 0 + 3.26 × 2
= 6.52 m/s upward
At this time, mis moving 6.52 m/s downward.
At time 2 s, mstops for a moment. But m1 is moving upward with velocity 6.52 m/s. It will continue to move till final velocity (at highest point) becomes zero.
Here, v = 0, u = 6.52 m/s
a = −g = − 9.8 m/s2
v = u + at = 6.52 + (−9.8)t
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
After this time, the mass m1 also starts moving downward.
So, the string becomes tight again after (2/3)s.


Q.24. In the following figure shows a uniform rod of length 30 cm and mass 3.0 kg. The strings shown in the figure are pulled by constant forces of 20 N and 32 N. Find the force exerted by the 20 cm part of the rod on the 10 cm part. All the surfaces are smooth and the strings and the pulleys are light.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Mass per unit length = 3/30 kg/cm = 0.10 kg/cm
Mass of the 10 cm part, m1 = 1 kg
Mass of the 20 cm part, m2 = 2 kg
Let F = contact force between them.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Adding both the equations, we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, contact force,
F = 20 + 1a
F = 20 + 1 × 4 = 24 N


Q.25. Consider the situation shown in the following figure  All the surfaces are frictionless and the string and the pulley are light. Find the magnitude of acceleration of the two blocks.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Mass of each block is 1 kg, HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
The free-body diagrams for both the boxes are shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
mgsinθ1 − T = ma    ...(i)
T − mgsinθ2 = ma    ...(ii)
Adding equations (i) and (ii),we get:
mg(sinθ1 − sinθ2) = 2ma
⇒ 2a = g (sinθ1 − sinθ2)
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE 


Q.26. A constant force F = m2g/2 is applied on the block of mass m1 as shown in the following figure. The string and the pulley are light and the surface of the table is smooth. Find the acceleration of m1.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

The free-body diagrams for both the blocks are shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram of block of mass m1,
m1a = T − F    ...(i)
From the free-body diagram of block of mass m2,
m2a = m2g − T    ...(ii)
Adding both the equations, we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the acceleration of mass m1, 
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.27. In the following figure, m1 = 5 kg, m2 = 2 kg and F = 1 N. Find the acceleration of either block. Describe the motion of m1 if the string breaks but F continues to act.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Let the acceleration of the blocks be a.
The free-body diagrams for both the blocks are shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
m1a = m1g + F − T    ...(i)
Again, from the free-body diagram,
m2a = T − m2g − F    ...(ii)
Adding equations (i) and (ii), we have:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Hence, acceleration of the block is 4.2 m/s2.
After the string breaks, m1 moves downward with force F acting downward. Then,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.28. Let m1 = 1 kg, m2 = 2 kg and m= 3 kg in the following figure. Find the accelerations of m1, m2 and m3. The string from the upper pulley to m1 is 20 cm when the system is released from rest. How long will it take before m1 strikes the pulley?
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

The free-body diagram for mass mis shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
The free-body diagram for mass m2 is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
The free-body diagram for mass m3 is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Suppose the block m1 moves upward with acceleration a1 and the blocks m2 and mhave relative acceleration a2 due to the difference of weight between them.
So, the actual acceleration of the blocks m1, m2 and m3 will be a1, (a1 − a2) and (a1 + a2), as shown.
From figure 2, T − 1g − 1a2= 0 ...(i)
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From equations (i) and (ii), eliminating T, we get:
1g + 1a2 = 4g + 4 (a1 + a2)
5a2 − 4a1 = 3g ...(iv)
From equations (ii) and (iii), we get:
2g + 2(a1 − a2) = 3g − 3 (a1 − a2)
5a1 + a2 = g ...(v)
Solving equations (iv) and (v), we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, accelerations of m1, m2 and m3 are HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Now, u = 0, s = 20 cm = 0.2 m
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.29. In the previous problem, suppose m2 = 2.0 kg and m3 = 3.0 kg. What should be the mass m, so that it remains at rest?
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

For m1 to be at rest, a1 = 0.
T − m1g = 0
T = m1g    ...(i)
For mass m2,
T/2 − 2g = 2a
T = 4a + 4g    ...(ii)
For mass m3,
3g – T/2= 2a
T = 6g − 6a    ...(ii)
From equations (ii) and (iii), we get:
3T – 12g = 12g – 2T
T = 24g/5= 4.08g
Putting the value of T in equation (i), we get:
m1 = 4.8kg


Q.30. Calculate the tension in the string shown in the following figure. The pulley and the string are light and all the surfaces are frictionless. Take g = 10 m/s2.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

The free-body diagrams for both the bodies are shown below:  
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
T + ma =mg    ...(i)
and T = ma    ...(ii)
From equations (i) and (ii), we get:
ma + ma = mg
⇒ 2ma = g
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From equation (ii),
T = ma = 5 N


Q.31. Consider the situation shown in the following figure. Both the pulleys and the string are light and all the surfaces are frictionless. (a) Find the acceleration of the mass M; (b) find the tension in the string; (c) calculate the force exerted by the clamp on the pulley A in the figure.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Let the acceleration of mass M be a.
So, the acceleration of mass 2M will be a/2
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(a) 2M(a/2) − 2T = 0
⇒ Ma = 2T
T + Ma − Mg = 0
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(b) Tension,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(c) Let T' = resultant of tensions
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Again, HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the force exerted by the clamp on the pulley is HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE at an angle of 45° with the horizontal.


Q.32. Find the acceleration of the block of mass M in the situation shown in the following figure. All the surfaces are frictionless and the pulleys and the string are light.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

The free-body diagram of the system is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Let acceleration of the block of mass 2M be a.
So, acceleration of the block of mass M will be 2a.
M(2a) + Mgsinθ − T = 0
⇒ T = 2Ma + Mgsinθ    ...(i)
2T + 2Ma − 2Mg = 0
From equation (i),
2(2Ma + Mgsinθ) + 2Ma − 2Mg = 0
4Ma + 2Mgsinθ + 2Ma − Mg = 0
6Ma + 2Mgsin30° + 2Mg = 0
6Ma = Mg
⇒ a = g/6
Hence, the acceleration of mass 
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.33. Find the mass M of the hanging block in the following figure that will prevent the smaller block from slipping over the triangular block. All the surfaces are frictionless and the strings and the pulleys are light.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

The free-body diagram of the system is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Block ‘m’ will have the same acceleration as that of M', as it does not slip over M'.
From the free body diagrams,
T + Ma – Mg = 0    ...(i)
T – M'a – Rsinθ = 0    ...(ii)
Rsinθ – ma = 0
Rcosθ – mg = 0
Eliminating T, R and a from the above equations, we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.34. Find the acceleration of the blocks A and B in the three situations shown in the following figure.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

(a) 5a + T − 5g = 0
From free-body diagram (1),
T = 5g − 5a  .....(i)
Again,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
⇒ T − 8g − 16a = 0
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From free-body diagram (2),
T = 8g + 16a ......(ii)
From equations (i) and (ii), we get:
5g − 5a = 8g + 16a
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the acceleration of the 5 kg mass is (9/7)m/s2 (upward) and that of the 4 kg mass is

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

(b) 

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
⇒ 8a − T = 0
⇒ T = 8a
Again, T + 5a − 5g = 0
From free body diagram-4,
8a + 5a − 5g = s0
⇒ 13a − 5g = 0
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Acceleration of mass 2 kg is HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE and 5 kg is 5g/13.
(c) T + 1a − 1g = 0
From free body diagram-5
T = 1g − 1a .....(i)
Again, from free body diagram-6,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
⇒ T − 4g − 8a = 0 .....(ii)
From equation (i)
1g − 1a − 4g − 8a = 0HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Acceleration of mass 1 kg is g/3 (upward)
Acceleration of mass 2 kg is 2g/3 (downward)
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.35. Find the acceleration of the 500 g block in the following figure.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Given,
m1 = 100 g = 0.1 kg
m= 500 g = 0.5 kg
m3 = 50 g = 0.05 kg
The free-body diagram for the system is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

From equation (ii),
T1 = 0.05g + 0.05a  .....(iv)
From equation (i),
T1 = 0.5g − 0.5a .....(v)
Equation (iii) becomes
T1 + 0.1a − T + 0.05g = 0
From equations (iv) and (v), we get:
0.05g + 0.05a + 0.1a − 0.5g + 0.5a + 0.05g = 0
0.65a = 0.4 g
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the acceleration of the 500 gm block is 8g/13 downward.


Q.36. A monkey of mass 15 kg is climbing a rope fixed to a ceiling. If it wishes to go up with an acceleration of 1 m/s2, how much force should it apply on the rope? If the rope is 5 m long and the monkey starts from rest, how much time will it take to reach the ceiling?

Mass of the monkey, m = 15 kg,
Acceleration of the monkey in the upward direction, a = 1 m/s2
The free-body diagram of the monkey is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
T − [15g + 15(a)] = 0
T − [15g + 15(1)] = 0
⇒ T = 5 (10 + 1)
⇒ T = 15 × 11 = 165 N
The monkey should apply a force of 165 N to the rope.
Initial velocity, u = 0
s = 5 m
Using, HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE we get:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
Hence, the time required to reach the ceiling is √10s.


Q.37. A monkey is climbing on a rope that goes over a smooth light pulley and supports a block of equal mass at the other end in the following figure. Show that whatever force the monkey exerts on the rope, the monkey and the block move in the same direction with equal acceleration. If initially both were at rest, their separation will not change as time passes.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Suppose the monkey accelerates upward with acceleration a and the block accelerates downward with acceleration a'.
Let force exerted by the monkey be F.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram of the monkey, we get:
F− mg − ma = 0    ...(i)
⇒ F = mg + ma
Again, from the free-body diagram of the block,
F + ma' − mg = 0
mg + ma + ma' − mg = 0            [From (i)]
⇒ ma = −ma'
⇒ a = −a'
If acceleration −a'  is in downward direction then the acceleration a' will be in upward direction.
This implies that the block and the monkey move in the same direction with equal acceleration.
If initially they were at rest (no force is exerted by the monkey), then their separation will not change as time passes because both are moving  same direction with equal acceleration.


Q.38. The monkey B, shown in the following figure, is holding on to the tail of monkey A that is climbing up a rope. The masses of monkeys A and B are 5 kg and 2 kg, respectively. If A can tolerate a tension of 30 N in its tail, what force should it apply on the rope in order to carry monkey B with it? Take g = 10 m/s2.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

Let the acceleration of monkey A upwards be a, so that a maximum tension of 30 N is produced in its tail.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
T − 5g − 30 − 5a = 0    ...(i)
30 − 2g − 2a = 0    ...(ii)
From equations (i) and (ii), we have:
T  = 50 + 30 +( 5 × 5) = 105 N   (max.)
and a = 5 m/s2
So, A can apply a maximum force of 105 N on the rope to carry monkey B with it.
For minimum force, there is no acceleration of A and B. HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEET1 = weight of monkey B
⇒ T1 = 20 N
Rewriting equation (i) for monkey A, we get:
T − 5g − 20 = 0
⇒ T = 5g + 20 = 50 + 20  = 70 N
∴ To carry monkey B with it, monkey A should apply a force of magnitude between 70 N and 105 N.


Q.39. In the following figure shows a man of mass 60 kg standing on a light weighing machine kept in a box of mass 30 kg. The box is hanging from a pulley fixed to the ceiling by a light rope, the other end of which is held by the man himself. If the man manages to keep the box at rest, what is the weight recorded on the machine? What force should he exert on the rope to record his correct weight on the machine?
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

(i) Given, mass of the man = 60 kg
Let W' = apparent weight of the man in this case
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram of the man,
W' + T − 60g = 0
⇒ T = 60g − W'    ...(i)
From the free-body diagram of the box,
T − W' = 30g = 0    ...(ii)
From equation (i), we get:
60g − W' − W' − 30g = 0
⇒ W' = 15g
Hence, the weight recorded on the machine is 15 kg.
(ii) To find his actual weight, suppose the force applied by the men on the rope is T because of which the box accelerates upward with an acceleration a'. Here we need to find T'
Correct weight = W = 60g
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram of the man,
T' + W − 60g − 60a = 0
⇒ T' − 60a = 0            
⇒ T' = 60a    ...(i)
From the free-body diagram of the box,
T' − W − 30g − 30a = 0
⇒ T' −  60g − 30g − 30a = 0
⇒ T' = 30a − 900     ...(ii)
From equations (i) and (ii), we get:
T' = 2T' − 1800
T' = 1800 N
So, the man should exert a force of 1800 N on the rope to record his correct weight on the machine.

Q.40. A block A can slide on a frictionless incline of angle θ and length l, kept inside an elevator going up with uniform velocity v in the following figure. Find the time taken by the block to slide down the length of the incline if it is released from the top of the incline.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
The force on the block which makes the body move down the plane is the component of its weight parallel to the inclined surface.
F = mg sinθ
Acceleration, g = sin θ
Initial velocity of block, u = 0
Distance to be covered
s = l
a = g sin θ
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.41. A car is speeding up a horizontal road with acceleration a. Consider the following situations in the car: (i) A ball suspended from the ceiling by a string is maintaining a constant angle with the vertical. Find this angle. (ii) A block is kept on a smooth incline and does not slip on the incline. Find the angle of the incline with the horizontal.

Let the pendulum (formed by the ball and the string) make angle θ with the vertical.
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
From the free-body diagram,
Tcosθ − mg = 0
Tcosθ = mg
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
And, ma − T sin θ = 0
⇒ ma = T sin θ
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the angle formed by the ball with the vertical is HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
(ii) Let the angle of the incline be θ.
From the diagram,
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
⇒ ma cos θ = mg sin θ
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
So, the angle of incline is HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE


Q.42. A block is kept on the floor of an elevator at rest. The elevator starts descending with an acceleration of 12 m/s2. Find the displacement of the block during the first 0.2 s after the start. Take g = 10 m/s2.

The free-body diagram of the system is shown below:
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
The two bodies are separated because the elevator is moving downward with an acceleration of 12 m/s2 (>g) and the body moves with acceleration, g = 10 m/s2 [Freely falling body]
Now, for the block:
g = 10 m/s2, u = 0, t = 0.2 s
So, the distance travelled by the block is given by
HC Verma Questions and Solutions: Chapter 5- Newton`s Laws of Motion- 2 | HC Verma Solutions - JEE
= 0 . 2 m = 20 cm
The displacement of the body is 20 cm during the first 0.2 s.

The document HC Verma Questions and Solutions: Chapter 5- Newton's Laws of Motion- 2 | HC Verma Solutions - JEE is a part of the JEE Course HC Verma Solutions.
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FAQs on HC Verma Questions and Solutions: Chapter 5- Newton's Laws of Motion- 2 - HC Verma Solutions - JEE

1. What are Newton's three laws of motion?
Ans.Newton's three laws of motion are: 1. <b>First Law</b> (Law of Inertia): An object at rest stays at rest, and an object in motion stays in motion with the same speed and in the same direction unless acted upon by a net external force. 2. <b>Second Law</b> (Law of Acceleration): The acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass, expressed mathematically as F = ma. 3. <b>Third Law</b> (Action and Reaction): For every action, there is an equal and opposite reaction.
2. How do you apply Newton's second law in solving problems?
Ans.To apply Newton's second law (F = ma), first identify all the forces acting on the object and determine the net force by vector addition. Then, divide the net force by the mass of the object to find the acceleration. Use the relationship to solve for unknowns, such as force, mass, or acceleration, depending on the problem.
3. What is the significance of friction in Newton's laws of motion?
Ans.Friction is a force that opposes the motion of an object. It plays a crucial role in Newton's laws, especially in real-world applications. For instance, when calculating net forces, friction must be accounted for to accurately determine the motion of objects. It can affect both the acceleration (as described in the second law) and the equilibrium of objects (related to the first law).
4. How do mass and weight differ in the context of Newton's laws?
Ans.Mass is a measure of the amount of matter in an object and remains constant regardless of location. Weight, however, is the force exerted by gravity on that mass and can change depending on the gravitational field strength. According to Newton's second law, weight can be calculated as W = mg, where g is the acceleration due to gravity.
5. Can you give an example of Newton's third law in everyday life?
Ans.An example of Newton's third law in everyday life is when you sit in a chair. Your body exerts a downward force on the chair (action), and the chair exerts an equal and opposite force upward on your body (reaction). This interaction keeps you in equilibrium and allows you to remain seated.
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