If the coefficient of friction between A and B is H, the maximum horizontal acceleration of the wedge A for which В will remain at rest w.r.t the wedge is: B A А 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

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

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

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 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^@ ]

A block of mass m is placed on a wedge of mass M. Coefficient of friction between them is mu gt cot theta. The minimum acceleration of the wedge at which block appears stationary relative to wedge is

A block of mass 2 kg is kept on a smooth wedge of mass 3 kg and wedge is kept on a rough horizontal surface. A vertical force of 60 N is applied on the minimum coefficient of friction between the wedge and horizontal surface, so that wedge remains at rest during the motion of block on the wedge ?

A block of mass 5 kg is kept against an accelerating wedge with a wedge angle of 45^(@) to the horizontal. The coefficient of friction between the block and the wedge is mu = 0.4 . What is the minimum absolute value of the acceleration of the wedge to keep the block steady? [Assume, g = 10 m/s^(2) ]

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:

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: