In the figure the plank resting on two cylinders is horizontal. The plank is pulled to the right such that the centre of smaller cylinder moves with a constant velocity `v`. Friction is large enough to prevent slipping at all surfaces. Find-
(a) The velocity of the centre of larger cylinder.
(b) The ratio of accelerations of the points of contact of the two cylinders with the plank.

Velocity of the centre of a small cylinder is v . There is no slipping anywhere. The velocity of the centre of the larger cylinder is

In the figure shown, the plank is being pulled to the right with a constant speed v . If the cylinder does not slip then: .

In the figure shown, the light thread is tightly wrapped on the cylinder and masses of plank and cylinder are same each equal to m . An external agent begins to pull the plank to the right with a constant force F. The friction between the plank and the cylinder is large enough to prevent slipping. Assume that the length of the plank is quite large and the cylinder does not fall off it for the time duration concerned. (a) Find the acceleration of the cylinder. (Hint : don’t write any equations) (b) Find the kinetic energy of the system after time t .

The figure shows a fixed inclined plane on which a plank is being pulled upwards such that the center C of the solid cylinder remains at rest with respect to ground. If no slipping takes place between the cylinder and the plank, then the acceleration of the planks is

A cylinder is rolling without slipping on a plank which is also moving with speed 10m//s on a horizontal surface as shown. The speed of centre of the cylinder is 20m//s . The mass of cylinder is 2kg . The kinetic energy of the cylinder when observed from ground is

A uniform cylinder of mass m rests on two rough horizontal planks. A thread is wound on the cylinder. The hanging end of the thread is pulled vertically down with a constant force F

A uniform cylinder is lying on a rough sheet of paper as shown in fig. The strip is pulled horizontally to the right with a constant acceleration of a_(0) = 6 m//s^(2) . Initially the cylinder is located at a distance of L = 10 m from the left end of the strip. Find the velocity of the centre of the cylinder at the instant it moves off the edge of the strip. Assume that the cylinder does not slip.

A plank with a uniform sphere placed on it rests on a smooth horizontal plane. The plank is pulled to the right by a constant force F . It the sphere does not slip over the plank, then

A boy pushes a cylinder of mass M with the help of a plank of mass m as shown in figure. There is no slipping at any contact. The horizontal component of the force applied by the boy on the plank is F. Find (a) The acceleration of the centre of the cylinder (b) The friction force between the plank and the cylinder