In the system shown, the blocks A,B and C are of weight 4W, W and W respectively. The system set free. The tension in the string connecting the blocks B and C is

Three weight A ,B and C are connected by string as shown in the figure. The system moves over a frictionless pulley. The tension in the string connecting A and B is (where g is acceleration due to gravity)

Three blocks A,B and C of mass 10 kg each are hanging on a string passing over a fixed frictionless pulley as shown in figure. The tension in the string connecting blocks B and C is (g=10m//s^(2))

In the system shown in figure, the block A is released from rest. Find Tension in the string.

A uniform sphere of weight W and radius 5 cm is being held by string as shown in the figure. The tension in the string will be

Three weights are hanging over a smooth fixed pulley as shown in the figure. What is the tension in the string connecting weights B and C ?

In the arrangement shown in the figure, mass of the block B and A is 2m and m respectively. Surface between B and floor is smooth. The block B is connected to the block C by means of a string-pulley system. If the whole system is released, then find the minimum value of mass of block C so that A remains stationary w.e.t. B. Coefficient of friction between A and B is mu.

Three blocks A, B and C of masses 5 kg, 10 kg and 15 kg respectively connected by two ideal strings are present on a smooth horizontal surface. An external horizontal force of 30 N acts on the block A to pull the system. Find the difference in the tensions in strings connecting A and B and, B and C.

Calculate the force P required to cause the block of weight W_(2)=200N just to slide under the block of weight W_(1)=100N shown in figure-2.43. What is the tension in the string AB and the normal forces acting between the blocks and that applied by ground on W_(2) ? Surfaces of the blocks in contact are rough and the frictional force between the two blocks is 25 N and that between lower block and ground is 75 N Take g = 10 m//s^(2) .

A small block of mass m is tied to the top of a smooth inclined plane with the help of a string of length L as shown in the figure. The inclined plane of inclination theta with horizontal is rotated with an angular velocity omega about a verticle axis passing through the end of the string fixed to the plane. (a) Find the maximum value of omega so that the block maintains contact with the inclined plane. (b) Find the ratio of the tension in the string and the normal reaction between the block and the plane.

The blocks B and C in the figure have mass m each. The strings AB and BC are light, having tensions T_(1) and T_(2) respectively. The system is in equilibrium with a constant horizontal force mg acting on C.