A `1kg` block `B` rests as shown on a bracket `A` of same mass. Constant forces `F_(1)=20N` and `F_(2)=8N` start to act at time `t=0` when the distance of block `B` from pulley is `50cm`. Time when block `B` reaches the pulley is` .`(` Assume that friction is absent every where. Pulley and string are light.

A block of mass 2 kg is plased on a smooth horizontal surface. Two forces F_(1)=20 N and F_(2)=5 N start acting on the block in opposite directions as shown. If block gets displaced by 5 m in the direction of net force then work done by F_(2) is :-

In the given figure, Find mass of the block A, if it remains at rest, when the system is released from rest. Pulleys and strings are massless. [g=10m//s^(2)]

When F = 2N, the frictional force between 5 kg block and ground is

A block resting on a smooth inclined plane is acted upon by a force F as shown. If mass of block is 2 kg and F = 20 N and sin37^(@)=3//5, the acceleration of block is

A 1 kg block situated on a rough incline is connected to a spring constant 100 Nm^(-1) as shown in figure . The block is released from rest with the spring in the unstretched position . The block moves 10 cm down the incline before coming to rest . Find the coefficient of friction between the block and the incline .Assume that the spring has a negligible mass and the pulley is frictionless.

A block rest on a rough inclined plane as shown in fig. A horizontal force F is applied to it (a) Find out the force of reaction, (b) Can the force of friction be zero if yes when? And (c) Assuming that fricition is not zero find its magnitude and direction of its limiting value.

Given in figure are two blocks A and B of weight 20N and 100N, respectively. These are being pressed against a wall by a force F as shown. If the coefficient of friction between the blocks is 0.1 and between block B and the wall is 0.15, the frictional force applied by the wall on block B is:

Block A and C starts from rest and move to the right with acceleration a_(A)=12tms^(-2) and a_(C )=3ms^(-2) . Here t is in second. The time when block B again comes to rest is

A block A of m ass rests on a horizontal table. A lig h t strin g connected to it passesover a frictionless pulley at the edge of table an d from its other end another block B of mass m_(2) is su sp en d e d . The co efficien t of k in eticfriction between the block and the table is mu_(k) hen the block A is sliding on the table, the ten sio n in the string i s :

The wires A and B shown in Fig. are made of the same material and have radii r_(A) and r_(B) , respectively. The block between them has a mass m . When the force F is mg//3 , one of the wires breaks. Then