A spool of mass `M` and radius `2R` lies on an inclined plane as shown in the figure. A light thread is wound around the connecting tube of the spool and its free end carries a weight of mass `m`. The value of `m` so that system is in equilibrium is

A disc of mass M and radius R moves in the x-y plane as shown in the figure. The angular momentum of the disc at the instant shown is –

A solid sphere having mass m and radius r rolls down an inclined plane. Then its kinetic energy is

A hollow cylindrical pipe of mass M and radius R has a thin rod of mass m welded inside it, along its length. A light thread is tightly wound on the surface of the pipe. A mass m_(0) is attached to the end of the thread as shown in figure. The system stays in equilibrium when the cylinder is placed such that alpha = 30^(@) The pulley shown in figure is a disc of mass (M)/(2) (a) Find the direction and magnitude of friction force acting on the cylinder. (b) Express mass of the rod ‘m’ in terms of m_(0)

A particle of mass M rests on a rough inclined plane at an angle q to the horizontal ("sin" theta = (4)/(5)) . It is connected to another mass m as shown in fig. The pulley and string are light. The largest value of m for which equilibrium is possible is M. Find the smallest value of m for which equilibrium is possible

Two masses m and M are attached to the strings as shown in the figure. If the system is in equilibrium, then

A spool (consider it as a double disc system joined by a short tube at their centre) is placed on a horizontal surface as shown Fig. A light string wound several times over the short connecting tube leaves it tangentially and passes over a light pulley. A weight of mass m is attached to the end of the string. The radius of the connecting tube is r and mass of the spool is M and radius is R . Find the acceleration of the falling mass m . Neglect the mass of the connecting tube and slipping of the spool.

A disc of mass m and radius r is free to rotate about its centre as shown in the figure. A string is wrapped over its rim and a block of mass m is attached to the free end of the string. The system is released from rest. The speed of the block as it descends through a height h, is :-

A smooth rod is fixed at an angle alpha to the horizontal. A small ring of mass m can slide along the rod. A thread carrying a small sphere of mass M is attached to the ring. To keep the system in equilibrium, another thread is attached to the ring which carries a load of mass m_(0) at its end (see figure). The thread runs parallel to the rod between the ring and the pulley. All threads and pulley are massless. (a) Find m_(0) so that system is in equilibrium. (b) Find acceleration of the sphere M immediately after the thread supporting m_(0) is cut.

Two blocks are placed at rest on a smooth fixed inclined place. A force F acts on block of mass m_1 and is parallel to the inclined plane as shown in figure. Both blocks move up the incline. Then (i) Draw free body diagram blocks of mass m_1 and blocks mass m_2 (ii) Find acceleration of blocks of mass m_1 and blocks mass m_2 (iii) Find normal reaction between the blocks of mass m_1 and m_2