If the coefficient of friction between the wedge A and block B shown in the figure is `mu`, then the maximum possible horizontal acceleration of A for which B doesn’t slip is [ angle of inclination of wedge = `45^@` ]

If the coefficient of friction between A and B is mu , the maximum acceleration of the wedge A for which B will remain at rest with respect to the wedge is

A block of mass m is at rest relative to the stationary wedge of mass M. The coefficient of friction between block and wedge is mu . The wedge is now pulled horizontally with acceleration a as shown in figure. Then the minimum magnitude of a for the friction between block and wedge to be zero is:

In the adjoining figure, the coefficient of friction between wedge ( of mass M) and block ( of mass m) is mu . Find the minimum horizontal force F rquired to keep the block stationary with respect to wedge

In the adjoining figure, the coefficient of friction between wedge (of mass M ) and block (of mass m ) is mu . Find the minimum horizontal force F required to keep the block stationary with respect to wedge.

The coefficient of static friction between a block of mass m and an incline is mu_s=03 , a. What can be the maximum angle theta of the incline with the horizontal so that the block does not slip on the plane? b. If the incline makes an angle theta/2 with the horizontal, find the frictional force on the block.

A wedge B of mass 2 m is placed on a rough horizontal suface. The coefficient of friction between wedge and the horizontal surface is mu_(1) . A block of mass m is placed on wedge as shown in the figure. The coefficient of friction between block and wedge is mu_(2) . The block and wedge are released from rest. Q. Suppose the inclined surface of the wedge is at theta=37^(@) from angle from horizontal and mu_(2)=0 are wedge will remain in equilibrium if