System is released from rest. Moment of inertia of pulley 'I'. Find angular speed of pulley when `m_1` block falls by 'h'. (Given `m_1 gt m_2` and assume no slipping between string and pulley).

A block of mass m is suspended from a pulley in form of a circular disc of mass m & radius R. The system is released from rest, find the angular velocity of disc when block has dropped by height h. (there is no slipping between string & pulley)

Two' blocks of masses m, and m, are connected to the two ends of a string passing over a pulley as shown in figure. System hans vertically and blocks are held at rest. Assume that m_(1) gt m_(2) . Find the speed attained by the blocks when m, descends through a height h. Moment of inertia of the pulley is I and its radius is r. There is enough friction between string and pulley so that there is no slipping between them.

A string is would over a cylinder of mass M, radius R and moment of inertia I and then the string is would over the pulley as shown in the figure. If the system is released from rest then determine the tension is tring. Assume there is no slipping between string and pulley cylinder.

Figure shows a pulley of mass m and radius r with two blocks of masses m_(1) and m_(2) attached with a light and unstretchable string. Find the acceleration of the blocks, tensions in the string and the force exerted by the pulley on the celling from which it is hanging. Assume no slipping between the string and the wheel.

Consider the situation as shown. The pulley has a moment of inertia I, and radius r, the block is in equilibrium. Find the time period of mass m. Assume no slipping.

In a simple At wood machine, two unequal masses m_1 and m_2 are connected by string going over a clamped light smooth pulley . IN a typical arrangement m_1=300g and m_2=600g . The system is released from rest. A. Find the distance travelled byi the first block in the first two seconds. b. Find the tension in the string. c. Findthe force exerted by the clamp on teh pulley.

The pulley shown in figure has a moment of inertia I about it's axis and its radius is R. Find the magnitude of the acceleration of the two blocks. Assume that the string is light and does not slip on the pulley.

String is wrapped over a pulley and free end is fixed to the ceiling as shown in figure. Mass of the pulley is m and its radius is R. Assume that pulley is identical to dise. Calculate acceleration of pulley as it is allowed to fall by unwinding the string. Assume that string does not slip over the pulley.

Figure shows a composite pulley of that consist of two cylinders of ‘R’ '2 R' stacked coaxially. Moment of inertia of composite pulley is (MR^(2))/(4) .A light string is wound over pulley and another pulley 'A' of mass 'M' is hanged through the string as shown in figure If there were no friction between string and pulley ‘A’, then the acceleration of pulley ‘A’ will be -

Two masses M and m are connect by a light string gong over a pulley of radis r. The pulley is free to rotate about its axis which is kept horizontal. The moment of inertia of the pulley about the axis is I. The system is releaed from rest. Find the angular momentum fo teh system when teh mass Mhas descended through a height h. The string does not slip over the pulley.