A system is shown in figure. Blocks 2 & 3 kg are at rest then co-efficient of friction between 2 kg & incline is

A force of 200N is applied as shown in the figure on block of 3 kg. The coefficient of friction between the block and the wall is 0.3. Find the friction acting on the block. (in N) {Take g = 10 m//s^(2)

Three blocks A , B and C , whose masses are 9kg , 9kg and 18kg respectively as shown in the figure, are released from rest. The co-efficient of friction between block A and the horizontal surface is 0.5 & the co-efficient of friction between block B and the horizontal surface is 0.5 . Find the acceleration of block C just release [Take g=10m//s^(2) ]. All strings and pulleys are ideal

Two blocks of 2 kg and 4 kg are connected by a light string and kept on horizontal surface A force of 16 N is acted on 4 kg block horizontally as shown in figure. Besides ,it is given that coefficient of friction between 4 kg and ground is 0.3 and between 2 kg block and ground is 0.6 . Then frictional force between 2 kg block ground is

Two blocks of masses 4 kg and 2 kg are in contact with each other on an inclined plane of inclination 30^(@) as shown in the figure . The coefficient of friction between 4 kg mass and the inclined plane is 0.3 , whereas between 2 kg mass and the plane is 0.2 . find the contact force between the blocks .

Two blocks of mass 10 kg and 2 kg are connected by an ideal spring of spring constant K = 800 N//m and the system is placed on a horizontal surface as shown. The coefficient of friction between 10 kg block and surface is 0.5 but friction is absent between 2 kg and the surface. Initially blocks are at rest and spring is relaxed. The 2 kg block is displaced to elongate the spring by 1 cm and is then released. (a) Will 10 kg block move subsequently? (b) Draw a graph representing variation of magnitude of frictional force on 10 kg block with time. Time t is measured from that instant when 2 kg block is released to move.

Two blocks of masses 3 kg and 2 kg are placed side by side on an inclined as shown in figuire A force F = 292 A force F = 20N is active on 2 kg block along the inclined .The coefficient of friction between the block and the inclined is same and equal to 0.1 .Find the normal force exerted by 2 kg block on 3 kg block

A block A with mass 100kg is resting on another block B of mass 200kg. As shown in figure a horizontal rope tied to a wall hold it. The coefficient of friction between A and B is 0.2 while coefficient of friction between B and the ground is 0.3 . the minimum required force F to start moving B will be.

Two blocks of mass 10 kg and 2 kg are connected by an ideal spring of spring constant 1000 N/m and the system is placed on a horizontal surface as shown. The coefficient of friction between 10 kg block and surface is 0.5 but friction is assumed to be absent between 2 kg and surface. Initially blocks are at rest and spring is unstretched then 2 kg block is displaced by 1 cm to elongate the spring then released. Then the graph representing magnitude of frictional force on 10 kg block and time t is : (Time t is measured from that instant when 2 kg block is released to move)

A is a 100kg block, and B is a 200kg block. As shown in figure the block A is attached to a string tied to a wall. The coefficient of friction between A and B is 0.2 and the coefficient of fricition between B and floor is 0.3. Then calculate the minimum force required to move the block B. (take g=10m//s^(2) ).