Particles are released from rest A and side down the smooth surface of hight h to a conveyor B. The correct angular veleocity `omega` of the coneyor pulley of readius r to prevent any siding on the beit as the particles transfer to the conveyou is

Particles are released from rest A and slide down the smooth surface of hight h to a conveyor B. The correct angular veleocity omega of the coneyor pulley of radius r to prevent any sliding on the belt as the particles transfer to the conveyor is

A block A starts sliding on a smooth track from a height h as shown in the figure. The track smoothly joins into a conveyor belt which is being driven by a pulley of radius r. I the angular velocity omega of the pulley is such that the block A doesn't slip on the belt, the value of omega is

A particle of mass m is released from a height H on a smooth curved surface which ends into a vertical loop of radius R , as shown. Choose the correct alernative(s) if H=2R .

A particle of mass m oscillates inside the smooth surface a fixed pipe of radius R . The axis of the pipe is horizontal and the particle moves from B to A and back. At an instant the kinetic energy of the particle is K (say at position of the particle shown in figure ). Then choose the correct value of force applied by particle on the pipe at this instant.

A hemispherical bowl of radius R is rotating about its own axis (which is vertical) with an angular velocity omega . A particle on the frictionless inner surface of the bowl is also rotating with the same omega . The particle is a height h from the bottom of the bowl. (i) Obtain the relation between h and omega _________ (ii) Find minimum value of omega needed, in order to have a non-zero value of h _____________ .

A particle of mass 5kg is free to slide on a smooth ring of radius r=20cm fixed in a vertical plane. The particle is attached to one end of a spring whose other end is fixed to the top point O of the ring. Initially, the particle is at rest at a point A of the ring such that /_OCA=60^@ , C being the centre of the ring. The natural length of the spring is also equal to r=20cm . After the particle is released and slides down the ring, the contact force between the particle and the ring becomes zero when it reaches the lowest position B. Determine the force constant (i n xx 10^2Nm^-1) of the spring.

A large , heavy box is sliding without friction down a smooth plane of inclination theta . From a point P on the bottom of the box , a particle is projected inside the box . The initial speed of the particle with respect to the box is u , and the direction of projection makes an angle alpha with the bottom as shown in Figure . (a) Find the distance along the bottom of the box between the point of projection p and the point Q where the particle lands . ( Assume that the particle does not hit any other surface of the box . Neglect air resistance .) (b) If the horizontal displacement of the particle as seen by an observer on the ground is zero , find the speed of the box with respect to the ground at the instant when particle was projected .