In the system shown, pulley and strings are ideal. The vertically upward pull F is being increased gradually, find magnitude F and acceleration of the 5 kg block at the moment the 10 kg block leves the floor.

In the arrangement shown, the pulleys and the string are ideal. The acceleration of block B is.

In the arrangement shown, the pulleys and the strings are ideal.The acceleration of the block B is

In the shown mass pulley system, pulleys and string are massless. The one end of the string is pulleed by the force F=2mg . The acceleration of the block will be

In the shown mass pulley system, pulleys and string are massless. The one end of the string is pulleed by the force F=2mg . The acceleration of the block will be

In the shown mass pulley system, pulleys and string are massless. The one end of the string is pulleed by the force F=2mg . The acceleration of the block will be

In the shown mass pulley system, pulleys and string are massless. The one end of the string is pulled by the force F = mg. The acceleration of the block will be :

In the arrangement shown all pulleys and strings are ideal. A vertical downward force of 10N is needed to apply on block A to keep the system in equilibrium. If mass of B is 10kg then find the mass of A

In the system shown in the figure, the acceleration of 1 kg block is

Three blocks, placed on smooth horizontal surface are connected by ideal string and a disc shaped pulley of radius r, and mass m. Find the accelerations of the blocks. Masses of the blocks are given as M_(1) = 10kg, M_(2) = 5 kg , M_(3) = 2kg, m = 2kg .

A block is being pulled by a force F on a long frictionless level floor. Magnitude of the force is gradually increases from zero until the block lifts off the floor. Immediately before the block leaves the floor, its acceleration is