Two blocks of masses `2m` and `m` are connected by a light string going over a pulley of mass `2m` and radius `R` as shown in the figure. The system is released from rest. Find the angular momentum of system when the mass `2m` has descended through a height `h`. Assume no slipping.

Two blocks each of mass 4 kg connected by a light string which is passing over an ideal pulley is as shown in figure. If the system is released from rest then the acceleration (in m/ s^2 ) of centre of mass is (g = 10 m/ s^2 )

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.

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.

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.

Two blocks are connected by a long inextensible string passing over an ideal pulley as shown in the figure. If the system is released from rest then the common speed of blocks when block m_2 moves a distance I will be

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.

Two blocks of mass M and 2M are connected to the two ends of a light, inextensible string passing over an ideal pulley as shown in figure. The system is released from rest. (a) One second after the system is released, a particle of mass M hits the block of mass M and sticks to it. The particle hits the block with a speed of 10 m/s while travelling downward. Find the total distance travelled by block of mass 2M after it is released. (b) One second after the system is released, a particle of mass 2M hits the block of mass M and sticks to it. The particle hits the block with a speed of 10 m/s while travelling in upward direction. Find distance travelled by the block of mass 2M after it is released to the time it comes to rest for the first time (g = 10 m//s)^(2)

A mass string going over a clamped pulley of mass m supports a block of mass M as shown in the figure. The force on the pulley by the clamp is given