Moment of inertia of an object does not depend upon
1. | mass of object |
2. | mass distribution |
3. | angular velocity |
4. | axis of rotation |
A force is acting on a point . The torque acting about a point is
1. 0
2.
2.
4.
A thin uniform circular disc of mass \(M\) and radius \(R\) is rotating in a horizontal plane about an axis passing through its center and perpendicular to its plane with an angular velocity . Another disc of the same dimensions but of mass \(\frac{1}{4}M\) is placed gently on the first disc co-axially. The angular velocity of the system will be:
1. | 2. | ||
3. | 4. |
When a torque acting upon a system is zero, then which of the following will be constant
1. | force |
2. | Linear momentum |
3. | Angular momentum |
4. | Linear impulse |
A wheel whose moment of inertia is 12 has an initial angular velocity of 40 rad/sec. A constant torque of 20 Nm acts on the wheel. The time in which the wheel is accelerated to 100 rad/sec is
1. 72 seconds
2. 16 seconds
3. 8 seconds
4. 36 seconds
A flywheel is in the form of a uniform circular disc of radius 1 m and mass 2 kg. The work which must be done on it to increase its frequency of rotation from 5 rev to 10 rev is approximately
1. 1.5 x J
2. 3.0 x J
3. 1.5 x J
4. 3.0 x J
A constant torque acting on a uniform circular wheel changes its angular momentum from to in 4s. The magnitude of this torque is
1.
2.
3.
4.
A body rolls down an inclined plane without slipping. The fraction of total energy associated with its rotation will be
Where k is radius of gyration of the body about an axis passing through centre of mass and R is the radius of the body.
In the following figure, a weight W is attached to a string wrapped round a solid cylinder of mass M mounted on a frictionless horizontal axle at O.
If the weight starts from rest and falls a distance h, then its speed at that instant is
1. Proportional to \(\text R\)
2. Proportional to \(1 \over R\)
3. Proportional to \(1 \over R^2\)
4. Independent of \(\text R\)