The block shown is moving with constant velocity. Find `mu_(k)` between the block and the surface.

In the block moves up with constant velocity v m/s. Find F

The block A is moving downward with constant velocity v_(0.) Find the velocity of the block B. When the string makes an angle theta with the horizontal

The three block shown in fig. move with constant velocities. Find the velocity of blocks A and B. given V_(P2)=10ms^(-1) darr, V_(C)=2ms^(-1) uarr .

A 6 kg block is kept on an inclined rough surface as shown in figure.Find the force F requiredto (a) keep the block stationary. (b) move the block downwards with contact velocity and ( c) move the block upwards with an acceleration 4 m//s^(2) (Take g = 10 m//s^(2))

A block of mass m has initial velocity u having direction towards +x axis. The block stops after covering a distnce S causing similar extension in the spring of constant K holding it. If mu is the kinetic friction between the block and the surface on which it was moving, the distance S is given

A block of mass m is moving on a rough horizontal surface. mu is the coefficient of kinetic friction between the block and the surface. What is the net force exerted by the surface on the block?

If block A is moving horizontally with velocity v_(A) , then find the velocity of block B at the instant as shown in fig.

A block of mass m is pulled by a force of constant power P placed on a rough horizontal plane. The friction coefficient between the block and the surface is mu . Then

A block of mass m is attached to one end of a mass less spring of spring constant k. the other end of spring is fixed to a wall the block can move on a horizontal rough surface. The coefficient of friction between the block and the surface is mu then the compession of the spring for which maximum extension of the spring becomes half of maximum compression is .

Blocks shown in figure moves with constant velocity 20 m/s towards right. All surfaces in contact are rough. The friction force applied by B on A is