A solid cylinder C and a hollow pipe P of same diameter are in contact when they are released from rest as shown in the figure on a long incline plane. Cylinder C and pipe P roll with out slipping. Determine the clear gap (in m) between them after 4 seconds.

A solid cylinder and a hollow cylinder, both of the same mass and same external diameter are released from the same height at the same time on an inclined plane. Both roll down without slipping. Which one will reach the bottom first ?

A solid cylinder and a solid sphere, both having the same mass and radius, are released from a rough inclined plane of inclination theta one by one. They roll on the inclined plane without slipping. The force of friction that acts

A solid sphere, disc and solid cylinder, all of the same mass, are allowed to roll down (from rest) on inclined plane, them

A ring, a solid cylinder, a hollow sphere and a solid sphere are released from rest on an inclined plane from same level. If there is no slipping then which one of these will reach the ground at last?

A ring, cylinder and solid sphere are placed on the top of a rough incline on which the sphere can just roll without slipping. When all of them are released at the same instant from the same position, then

A sphere a disk and a hoop made of homogeneous materials have the same radius (10 cm) and mass (3kg) They are released from rest at the top of a 30^(@) incline and roll down without slipping through a vertical distance of 2m. (g=9.8m//s^(2)) (a). What are their speeds at the bottom? (b). findt the friction force f each case (c). if they start together at t=0 , at what time does each reach the bottom?

A wheel A is connected to a second wheel B by means of in extensible string, passing over a pulley C , which rotates about a fixed horizontal axle O , as shown in the figure. The system is released from rest. The wheel A rolls down the inclined plane OK thus pulling up wheel B which rolls along the inclined plane ON . Determine the velocity (in m/s) of the axle of wheel A , when it has traveled a distance s = 3.5 m down the to be slope. Both wheels and the pulley are assumed homogeneous disks of identical weight and radius. Neglect the weight of the string. The string does not slip over C . [Take alpha =53^@ and beta=37^@ ]

A wheel A is connected to a second wheel B by means of inextensible string, passing over a pulley C , which rotates about a fixed horizontal axle O , as shown in the figure. The system is released from rest. The wheel A rolls down the inclined plane OK thus pulling up wheel B which rolls along the inclined plane ON . Determine the velocity (in m/s) of the axle of wheel A , when it has travelled a distance s = 3.5 m down the to be slope. Both wheels and the pulley are assumed homogeneous disks of identical weight and radius. Neglect the weight of the string. The string does not over C . [Take alpha =53^@ and beta=37^@ ]

A ring of mass 0.3 kg and radius 0.1 m and a solid cylinder of mass 0.4 kg and of the same radius are given the same kinetic energy and released simultaneously on a flat horizontal surface towards a wall which is at the same distance from the ring and the cylinder. The rolling friction in both cases is negligible. which of them will reach the wall first

A solid cylinder of mass M and radius R rolls from rest down a plane inclined at an angle theta to the horizontal. The velocity of the centre of mass of the cylinder after it has rolled down a distance d is :