In the arrangement shown in the fig, block A is pulled so that it moves horizontally along the line AX with constant velocity u. Block B moves along the incline. Find the time taken by B to reach the pulley P if `u = 1m//s`. The string is inextensible.

In the arrangement shown, end A of light intextensible string is pulled with constant velocity v. the velocity of block B is

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

In the arrangement shown in fig neglect the masses of pulleys and string and also friction Calculate acceleration of blocks A and B

In the arrangement shown, the pulleys are smooth and the strings are inextensible. The acceleration of block B is :

A block of mass 4 kg is pulled along a smooth inclined plane of inclination 30^(@) with constant velocity 3 m/s as shown, power delivered by the force is

In the arrangement shown in the fig, end A of the string is being pulled with a constant horizontal velocity of 6 m//s . The block is free to slide on the horizontal surface and all string segments are horizontal. Find the velocity of point P on the thread.

In the arrangement shown in the figure, block A of mass 8 kg rests on a horizontal table having coefficient of friction mu = 0.5 . Block B has a mass of 6 kg and rests on a smooth incline having inclination angle theta = sin^(-1) ((2)/(5)) . All pulleys and strings are mass less . Mass of block C is M . [g = 10 m//s^(2)] (a) Find value of M for which block B does not accelerate (b) Find maximum value of M for which A does not accelerate.

In the arrangement shown, blocks A and B connected with an inextensible string move with velocities v_(1) and v_(2) along horizontal direction. The ratio of v_(2)/v_(1) is: