In the given figure find minimum force (in N) required to move block up the incline.

A block of mass m is lying on an inclined plane. The coefficient of friction between the plane and the block is mu . The force (F_(1)) required to move the block up the inclined plane will be:-

A block is moving on an inclined plane making an angle 45^@ with the horizontal and the coefficient of friction is mu . The force required to just push it up the inclined plane is 3 times the force required to just prevent it from sliding down. If we define N=10mu , then N is

A block of mass m=1/3 kg is kept on a rough horizontal plane. Friction coefficient is mu=0.75 . The work done by minimum force required to drag to the block along the plane by a distance 5m is :-

A block of mass 2 kg is kept on a rough horizontal floor an pulled with a force F. If the coefficient of friction is 0.5. then the minimum force required to move the block is :-

Find the minimum value of horizontal force (F) required on the block of mass m to keep it at rest on the wall. Given the coefficient of friction between the surfaces is mu .

Two block A and B are as shown in figure. The minimum horizantal force F applied to the block B for which slipping begins between B and ground is :

A block of mass m lies on wedge of mass Mas shown in figure. Find the minimum friction coeffcient required between wedge Mand ground so that it does not move while block m slips down on it.

A block of mass 1 kg is pushed up a surface inclined to horizontal at an angle of 30^(@) by a force of 10 N parallel to the inclined surface (figure) . The coefficient of friction between block and the incline is 0.1 .If the block is pushed up by 10 m along teh inclined calculate (a) work done against gravity (b) work done against force of friction (c ) increases in potential energy (d) increases in kinetic energy (e) work done by applied force

For the situation shown in the figure, what should be the value of force required to move the rod with constant velocity v = 2 m/s ?