The block A is kept over a plan B. The maximum horizontal acceleration of the system in order to prevent slipping of A over B is `a = 2 ms^(-2)` find the coefficient of friction between A and B

A block of mass 10kg is pushed by a force F on a horizontal rough plane is moving with acceleration 5ms^(-2) When force is doubled its acceleration becomes 18ms^(-2) Find the coefficient of friction between the block and rough horizontal plane (g =10ms^(-2)) .

Two blocks A and B are placed one over the other on a smooth horizontal surface. The maximum horizontal force that can be applied on the lower block A, so that A and B move without separation is 49N. The coefficient of friction between A and B is (take g = 9.8ms^(-2) )

A trolley A has a simple pendulum suspended from a frame fixed to its deck A block B is in contact on its vertical side. The trolley is on horizontal rails and accelerates towards the right, such that the block is just prevented from falling. If the value of coefficient of friction between A and B is 0.5 find the value of the inclination of the pendulum to the vertical.

A block of mass m is gently placed over a massive plank moving horizontal over a smooth surface with velocity 10 ms^(-1) . The coefficient of friction between the block and the plank is 0.2. The distance travelled by the block till it slides on the plank is [g = 10 ms^(-2)]

A block is kept on a horizontal table. The table is undergoing simple farmonic motion of frequency 3Hz in a horizontal plane. The coefficient of static friction between the block and the table surface is 0.72. find the maximum amplitude of the table at which the block does not slip on the surface g=10ms^(-1)

Two blocks A and B of masses m_(A) and m_(B) have velocity v and 2v respectively at a given instant A horizontal force F acts on the block A There is no friction between ground and block B and coefficient of friction between A and B is mu The friction

Two blocks A and B are connected to each other by a string and a spring, the string passes over a frictionless pulley as shown in Block B slides over the horizontal surface of a stationary block C and the block. A slides along the vertical side of C, both with same uniform speed. The coefficient of friction between the surface of the blocks is 0.2 Force constant of the spring is 1960 N//m if the mass of block A is 2 kg calculate the mass of the block B and the energy stored in the spring.

The ratio of acceleration of blocks A placed on smooth incline with block B placed on rough incline is 2:1 . The coefficient of kinetic friction between block B and incline is