In the adjacent figure the blocks A, B and C are in equilibrium. The spring of stiffness k is light and vertical. The horizontal string joining the block A to a fixed will is cut. If acceleration of B is `(ng)/4` then find the value of n, just after cutting the string.

The block shown in the figure in is equilibrium. Find acceleration of the block just after the string burns.

In the figure, blocks A and B of masses 2m and m are connected with a string and system is hanged vertically wioth the help of spring. Spring has negligible mass. Find out magnitude of acceleration of masses 2 m and m just after the instant when the string is cut

Block of mass m=10kg is suspended by two springs vertically as shown in the diagram. The block is at rest initially. Find the acceleration of block just after cutting the right spring.

System shown in fig is in equilibrium and at rest. The spring and string are massless now the string is cut. The acceleration of mass 2m and m just after the string is cut will be:

The system shown in the figure is in equilibrium and all the blocks are at rest. Assume that the masses of the strings, the pulley and the spring and negligible with respect to the masses of the blocks and friction is absent. Find the acceleration of block C, just after cutting the spring 1. [g=10ms^(-2)]

In the arrangement shown in figure. The strings are light and inextensible. The surface over which block are placed is smooth.Find (a) the acceleration of each block, (b) the tension in each string.

System shown in figure is equilibrium in vertical plane. Consider the string and spring to be massless. Both the blocks have same mass 'm' . If the string is cut, then just after cutting it :

The system shown in the following figure is in equilibrium and at rest. The spring and string are massless. Now, the string is cut. The acceleration of mass 2m and m, just after the string is cut, will be

A block A of mass 2m is hanging from a vertical massless spring of spring constant k and is in equilibrium. Another block B of mass m strikes the block A with velocity u and sticks to it as shown in the figure. The magnitude of the acceleration of the combined system of the blocks just after the collision is