A wedge of mass M is loaded with a sphere of mass m.If a horizontal force F is applied on the wedge, it remains in equilibrium.

A vertical rod of mass m is kept on a wedge of mass M. If a horizontal force F acts on the wedge and the rod is constrained to move vertically, after releasing the rod-wedge system, (a) find their speeds when the wedge moves through a distance x. (b) What is the power delivered by the rod on the wedge aftre a time t measured from the instant of release?

A wedge of mass M lies on a smooth fixed wedge of inclination theta . A particle of mass m lies on the wedge of mass M in the figure. All surfaces are frictionless and the distance of the block from the fixed wedge is l . Find. (a) Normal reaction between m and M (b) the time after which the particle will hit the fixed plane.

A smooth wedge of mass M is pushed with an acceleration a=gtantheta and a block of mass m is projected down the slant with a velocity v relative to the wedge. The horizontal force applied on the wedge is:

A ball of mass m is released from A inside a smooth wedge of mass m as shown in figure. What is the speed of the wedge when the ball reaches point B?

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

A wedge of mass M=4m lies on a frictionless plane. A particle of mass m approaches the wedge with speed v. there is no friction between the particle and the plane or between the particle and the wedge. The maximum height climbed by the particle on the wedge is given by

A wedge of mass M = 4m lies on a frictionless plane. A particle of mass m approaches the wedge with speed v. There is no friction between the particle and the plane or between the particle and the wedge. The maximum height climbed by the particle on the wedge is given by:

A block of mass m is placed on a wedge of mass M. Coefficient between then is mu lt cot theta . The wedge is given an acceleration to its left. Find the maximum acceleration at which block apears stationary relative 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.

A cube of mass m is placed on top of a wedge of mass 2m, as shown in figure. There is no friction between the cube and the wedge. The minimum co - efficient of friction between the wedge and the horizontal surface, so that the wedge does not move is