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Test: Rotational Motion - JEE MCQ

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30 Questions MCQ Test - Test: Rotational Motion

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Test: Rotational Motion - Question 1

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The moment of inertia of a body depends upon -

A.
mass only
B.
angular velocity only
C.
distribution of particles only
D.
mass and distribution of mass about the axis

Detailed Solution for Test: Rotational Motion - Question 1

I = mr², therefore it depends on body mass and its mass distribution.

Test: Rotational Motion - Question 2

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Two spheres of same mass and radius are in contact with each other. If the moment of inertia of a sphere about its diameter is I, then the moment of inertia of both the spheres about the tangent at their common point would be -

A.
3I
B.
7I
C.
4I
D.
5I

Detailed Solution for Test: Rotational Motion - Question 2

The moment of inertia of a sphere about its diameter is given as,
I=2/5 MR²
The moment of inertia of the sphere about the tangent is given as,
I′=2/5MR²+MR²
I′=7/5MR²
The total moment of inertia of both spheres about the common tangent is given as,
I_t=2I′
I_t=2×7/5MR²
I_t=7I

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Test: Rotational Motion - Question 3

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A disc of metal is melted to recast in the form of a solid sphere. The moment of inertias about a vertical axis passing through the centre would -

A.
decrease
B.
increase
C.
remains same
D.
nothing can be said

Detailed Solution for Test: Rotational Motion - Question 3

Moment of inertia will decrease, because
I_d=1/2mr² and I_s=2/5mr²,
the radius of sphere formed on recasting the disc will also decrease.

Test: Rotational Motion - Question 4

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The M.I. of a disc about its diameter is 2 units. Its M.I. about axis through a point on its rim and in the plane of the disc is

A.
4 unit
B.
6 unit
C.
8 unit
D.
10 unit

Detailed Solution for Test: Rotational Motion - Question 4

We know that for a disc of mass m and radius r
MI of a disc about its diameter = mr²/4 = 2
And also MI about a point on its rim = mr²/4 + mr²
= 5mr²/4
= 5 x 2 = 10

Test: Rotational Motion - Question 5

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A solid sphere and a hollow sphere of the same mass have the same moments of inertia about their respective diameters, the ratio of their radii is

A.
(5)^1/2 : (3)^1/2
B.
(3)^1/2 : (5)^1/2
C.
3 : 2
D.
2 : 3

Detailed Solution for Test: Rotational Motion - Question 5

We know moment of inertia of solid sphere I_s=2/5m_sR_s² and
moment of inertia of hollow sphere I_H=2/3m_HR_H² As per question Is=IH
Now,
2/5msRs2=2/3mHRH2
as the masses are equal the ratio of their radii will be
R_s² /R_H² =2/3/2/5=√5/3=(5)^1/2: (3)^1/2

Test: Rotational Motion - Question 6

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A stone of mass 4kg is whirled in a horizontal circle of radius 1m and makes 2 rev/sec. The moment of inertia of the stone about the axis of rotation is

A.
64 kg × m²
B.
4 kg × m²
C.
16 kg × m²
D.
1 kg × m²

Detailed Solution for Test: Rotational Motion - Question 6

Moment of Inertia = MR²
= 4 × 1
= 4 kg-m²

Test: Rotational Motion - Question 7

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Three rings, each of mass P and radius Q are arranged as shown in the figure. The moment of inertia of the arrangement about YY' axis will be

A.
PQ²
B.
PQ²
C.
PQ²
D.
PQ²

Detailed Solution for Test: Rotational Motion - Question 7

For ring 1
(MOI)1 = MOI about diameter + PQ²
MOI about diameter = ½ PQ²
(MOI)1 = 3/2 PQ²
Similarly, (MOI)2 = 3/2 PQ²
(MOI)3 = ½ PQ²
Total MOI = 7/2 PQ²

Test: Rotational Motion - Question 8

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A circular disc A of radius r is made from an iron plate of thickness t and another circular disc B of radius 4r is made from an iron plate of thickness t/4. The relation between the moments of inertia I_A and I_B is

A.
I_A > I_B
B.
I_A = I_B
C.
I_A < I_B
D.
depends on the actual values of t and r.

Detailed Solution for Test: Rotational Motion - Question 8

Test: Rotational Motion - Question 9

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The moment of inertia of a uniform semicircular wire of mass M and radius r about a line perpendicular to the plane of the wire through the centre is

A.
Mr²
B.
C.
D.

Detailed Solution for Test: Rotational Motion - Question 9

The formula for the MOI of a uniform semicircular ring about a perpendicular line is ½ Mr²

Test: Rotational Motion - Question 10

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Let I_A and I_B be moments of inertia of a body about two axes A and B respectively. The axis A passes through the centre of mass of the body but B does not.

A.
I_A < I_B
B.
If I_A < I_B, the axes are parallel.
C.
If the axes are parallel, I_A < I_B
D.
If the axes are not parallel, I_A ³ I_B

Detailed Solution for Test: Rotational Motion - Question 10

If the axes are parallel, we use the formula:
Io = Icm + md²
For the first body the distance between the axis and the axis passing through C.O.M is 0
Therefore, Io = Icm + m(0)² = lcm since it is mentioned in question
Whereas for the second body it is not passing through the C.O.M therefore, there is some distance between the axes, say 'd'
So, Io = Icm + md²

Test: Rotational Motion - Question 11

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For the same total mass which of the following will have the largest moment of inertia about an axis passing through its centre of mass and perpendicular to the plane of the body

A.
a disc of radius a
B.
a ring of radius a
C.
a square lamina of side 2a
D.
four rods forming a square of side 2a

Detailed Solution for Test: Rotational Motion - Question 11

Moment of inertia depends on distribution of mass around axis. The more the mass near the axis lesser is the moment of inertia. Four rods forming a square have more moment of inertia because of less mass near axis.

Test: Rotational Motion - Question 12

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Moment of inertia of a thin semicircular disc (mass = M & radius = R) about an axis through point O and perpendicular to plane of disc, is given by :

A.
B.
C.
D.
MR²

Detailed Solution for Test: Rotational Motion - Question 12

Mass of semicircular disc = M
Suppose there is a circular disc of mass 2M, then
Moment of intertia of circular disc = ½ (2M)R²
Moment of intertia of circular disc = ½ (2M)R² = MR²
=> So, Moment of intertia of semi-circular disc = ½ MR²

Test: Rotational Motion - Question 13

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A rigid body can be hinged about any point on the x-axis. When it is hinged such that the hinge is at x, the moment of inertia is given by

I = 2x² - 12x + 27 The x-coordinate of centre of mass is

A.
x = 2
B.
x = 0
C.
x = 1
D.
x = 3

Detailed Solution for Test: Rotational Motion - Question 13

Moment of inertia is minimum at centre of mass of the body.
I = minimum for centre of mass
Therefore x co-ordinate of centre of mass is 3 unit.

Test: Rotational Motion - Question 14

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Consider the following statements

Assertion (A) : The moment of inertia of a rigid body reduces to its minimum value as compared to any other parallel axis when the axis of rotation passes through its centre of mass.

Reason (R) : The weight of a rigid body always acts through its centre of mass in uniform gravitational field. Of these statements :

A.
both A and R are true and R is the correct explanation of A
B.
both A and R are true but R is not a correct explanation of A
C.
A is true but R is false
D.
A is false but R is true

Detailed Solution for Test: Rotational Motion - Question 14

Moment of inertia about its centroidal axis has a minimum value as the centroidal axis has mass evenly distributed around it thereby providing minimum resistance to rotation as compared to any other axis. Also the statement-2 is correct but is not the correct explanation for statement-1.

Test: Rotational Motion - Question 15

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A body is rotating uniformly about a vertical axis fixed in an inertial frame. The resultant force on a particle of the body not on the axis is

A.
vertical
B.
horizontal and skew with the axis
C.
horizontal and intersecting the axis
D.
none of these

Detailed Solution for Test: Rotational Motion - Question 15

Since the axis is vertical, the force will be horizontal and since it is centripetal force it will intersect the axis.

Test: Rotational Motion - Question 16

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One end of a uniform rod of mass m and length I is clamped. The rod lies on a smooth horizontal surface and rotates on it about the clamped end at a uniform angular velocity w. The force exerted by the clamp on the rod has a horizontal component

A.
mw²l
B.
zero
C.
mg
D.

Detailed Solution for Test: Rotational Motion - Question 16

Consider a rod of length l and mass m rotating with an angular velocity of w
dF = dm l w²
dF = (m/l) dμ l w²
Integrating
F = ½mlw²

Test: Rotational Motion - Question 17

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A rod of length 'L' is hinged from one end. It is brought to a horizontal position and released. The angular velocity of the rod when it is in vertical position is

Detailed Solution for Test: Rotational Motion - Question 17

Test: Rotational Motion - Question 18

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A disc of radius 2m and mass 200kg is acted upon by a torque 100N-m. Its angular acceleration would be

A.
1 rad/sec²
B.
0.25 rad/sec²
C.
0.5 rad/sec²
D.
2 rad/sec².

Detailed Solution for Test: Rotational Motion - Question 18

F = ma
a = Wr
So, F = mwr
a = wr = acceleration
m = 200kg
F = 100 n-m, r = 2m, w = to be calculated
100 = 200 x w²
w = 0.25 rad/sec²

*Multiple options can be correct

Test: Rotational Motion - Question 19

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On applying a constant torque on a body

A.
Linear velocity may be increases
B.
Angular velocity may be increases
C.
It will rotate with constant angular velocity
D.
It will move with constant velocity

Detailed Solution for Test: Rotational Motion - Question 19

If a constant torque is applied it is possible that a positive angular acceleration gets generated which can generate a positive acceleration and hence increasing both velocity and angular velocity.

Test: Rotational Motion - Question 20

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A wheel starting with angular velocity of 10 radian/sec acquires angular velocity of 100 radian/sec in 15 seconds. If moment of inertia is 10kg-m², then applied torque (in newton-metre) is

A.
900
B.
100
C.
90
D.
60

Detailed Solution for Test: Rotational Motion - Question 20

I(ωf - ωi)/t = τ
Hence, τ = 60

Test: Rotational Motion - Question 21

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An automobile engine develops 100H.P. when rotating at a speed of 1800 rad/min. The torque it delivers is

A.
3.33 W-s
B.
200W-s
C.
248.7 W-s
D.
396 W-s

Detailed Solution for Test: Rotational Motion - Question 21

100 HP = 74570 W or 74.57 KW Now, P = 2*π*N*T/60 where, P is the power (in W), N is the operating speed of the engine (in r.p.m.) and T is the Torque (in N.m). Therefore, 74570 = 2*π*1800*T/60 i.e. T = 395.606 N.m

Test: Rotational Motion - Question 22

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The moment of inertia and rotational kinetic energy of a fly wheel are 20kg-m²and 1000 joule respectively. Its angular frequency per minute would be -

A.
600/π
B.
25/π²
C.
5/π
D.
300/π

Detailed Solution for Test: Rotational Motion - Question 22

Rotational K.E. = ½ × moment of inertia × square of angular velocity = ½Iw²

Test: Rotational Motion - Question 23

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Calculate the M.I. of a thin uniform ring about an axis tangent to the ring and in a plane of the ring, if its M.I. about an axis passing through the centre and perpendicular to plane is 4 kg m².

A.
12 kg m²
B.
3 kg m²
C.
6 kg m²
D.
9 kg m²

Detailed Solution for Test: Rotational Motion - Question 23

At tangent I =MR²/2 + MR² --- (1)
MR²/2 = 4, MR² = 8 then substitute in (1) you will get I = 12, this is for tangent perpendicular to plane then divide by 2 you will get tangent along the plane

Test: Rotational Motion - Question 24

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A torque of 2 newton-m produces an angular acceleration of 2 rad/sec² a body. If its radius of gyration is 2m, its mass will be:

A.
2 kg
B.
1/4 kg
C.
1/2 kg
D.
4 kg

Detailed Solution for Test: Rotational Motion - Question 24

Test: Rotational Motion - Question 25

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A particle is at a distance r from the axis of rotation. A given torque t produces some angular acceleration in it. If the mass of the particle is doubled and its distance from the axis is halved, the value of torque to produce the same angular acceleration is

A.
t/2
B.
t
C.
2t
D.
4t

Detailed Solution for Test: Rotational Motion - Question 25

We know that from some torque t, angular acceleration a produced can be find by,
t = I a, where I is moment of inertia = mr²
Thus we get a = t / mr²
Now we have 2m and r/²
Thus a = t / mr² = T / 2m(r/2)²
Thus we get T = t/2

Test: Rotational Motion - Question 26

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A weightless rod is acted on by upward parallel forces of 2N and 4N ends A and B respectively. The total length of the rod AB = 3m. To keep the rod in equilibrium a force of 6N should act in the following manner :

A.
Downwards at any point between A and B.
B.
Downwards at mid point of AB.
C.
Downwards at a point C such that AC = 1m.
D.
Downwards at a point D such that BD = 1m.

Detailed Solution for Test: Rotational Motion - Question 26

Test: Rotational Motion - Question 27

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A right triangular plate ABC of mass m is free to rotate in the vertical plane about a fixed horizontal axis through A. It is supported by a string such that the side AB is horizontal. The reaction at the support A is :

A.
B.
C.
D.
mg

Detailed Solution for Test: Rotational Motion - Question 27

The distance of Centre Of Mass of the given right angled triangle is 2L/3 along BA and L/3 along AC from the point B.
Force of magnitude mg is acting downwards at its COM.
Moment balance around B gives:
mg(2L/3)−F_A(L)=0
(Moment= × =rFsin(θ)=F(rsin(θ))=Fr⊥)
∴F_A=2mg/3

Test: Rotational Motion - Question 28

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In an experiment with a beam balance on unknown mass m is balanced by two known mass m is balanced by two known masses of 16 kg and 4 kg as shown in figure.

The value of the unknown mass m is

A.
10 kg
B.
6 kg
C.
8 kg
D.
12 kg

Detailed Solution for Test: Rotational Motion - Question 28

Test: Rotational Motion - Question 29

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A homogeneous cubical brick lies motionless on a rough inclined surface. The half of the brick which applies greater pressure on the plane is :

A.
Left half
B.
Right half
C.
Both applies equal pressure
D.
The answer depend upon coefficient of friction

Detailed Solution for Test: Rotational Motion - Question 29

As weight of the body (mg) acts along the left side i.e. mg sinx acts along flow of object.
mgcosx acts perpendicular to flow of the object.
The pressure of right half comes on left half hence left half has maximum pressure.

Test: Rotational Motion - Question 30

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Consider the following statements

Assertion (A) : A cyclist always bends inwards while negotiating a curve

Reason (R) : By bending he lowers his centre of gravity Of these statements,

A.
Both A and R are true and R is the correct explanation of A
B.
Both A and R are true but R is not the correct explanation of A
C.
A is true but R is false
D.
A is false but R is true

Detailed Solution for Test: Rotational Motion - Question 30

B is correct. The reason is a part of the question.

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