Two balls A and B of angular velocities `omega_(A)` and `omega_(B)` collide with each other. Then, after collision

A clutch assembly consists of two discs A and B of moment of inertia 2I and I respectively, one being the engine fly wheel, the other one is the clutch plate. The discs are initially rotaing with angular velocities omega_(A)=omega and omega_(B)=2omega as shown in fig. When the two disc are brought into contact the discs rub against each other and eventually reach a common angualr velocity omega . (a) Derive an expressio for omega (b) What is the angular impulse of friction on any one of the discs?

Two discs A and B are in contact and rotating with angular velocity with angular velocities omega_(1) and omega_(2) respectively as shown. If there is no slipping between the discs, then

A uniform solid sphere of radius r is rolling on a smooth horizontal surface with velocity v and angular velocity omega = (v=omega r) . The sphere collides with a sharp edge on the wall as shown in figure. The coefficient of friction between the sphere and the edge mu=1//5 . Just after the collision the angular velocity of the sphere becomes equal to zero. The linear velocity of the surface just after the collision is equal to

Two particles of mass m_(A) and m_(B) and their velocities are V_(A) and V_(B) respectively collides. After collision they interchanges their velocities, then ratio of m_(A)/m_(B) is

A sphere of radius R and mass M collides elastically with a cubical block of mass M and side 2R . The entire system is on a smooth horizontal ground. Given that the sphere was rolling without slipping with an angular velocity omega at the time of collision. The velocities of the sphere and the block after the collision are

Two balls are moving towards each other on a vertical line collides with each other as shown. Find their velocities just after collision.

Two indentical balls A and B moving with velocities u_(A) and u_(B) I the same direction collide. Coefficient of restitution is e. (a) Deduce expression for velocities of the balls after the collision. (b) If collision is perfectly elastic, what do you observe?

A ball of mass 1 kg moving with a velocity of "0.4 ms"^(-1) collides with another stationary ball. After the collision, the first ball moves with a velocity of 0.3ms^(1) in a direction making an angle of 90^(@) with its initial direction. The momentum of the second ball after the collision will be (in kg ms^(-1) )

Two identical balls A and B are released from the position shown in Fig. They collide elastically with each other on the horizontal portion. The ratio of heights attained by A and B after collision is (neglect friction)