A particle of mass m is pulled along an arbitrary curved surface without acceleration as shown in figure. Coefficient of friction between surface and particle is `mu`. Then


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A crate of mass m is pulled with a force F along a fixed right angles horizontal trough as in figure. The coefficient of kinetic friction between the crate and the trough is mu . Find the value of force F required to pull it along the trough with constant velocity.

A block of mass m is slowly pulled along a curved surface from position 1 and 2. If the coefficient of kinetic friction between the block and surface is mu , find the work done by the applied force.

A uniform ring of mass m is placed on a rough horizontal fixed surface as shown in the figure. The coefficient of friction between the left part of the ring and left part of the horizontal surface is mu_(1)=0.6pi and between right half and the surface is mu_(2)=0.2pi . At the instant shown, now the ring has been imparted an angular velocity in clockwise sense in the figure shown. At this moment magnitude of acceleration of centre O of the ring (in m//s^(2) ) is (take g=10m//s^(2) )

Two block of masses m1 and m2 are connected with a massless unstretched spring and placed over a plank moving with an acceleration 'a' as shown in figure. The coefficient of friction between the blocks and platform is mu

A point particle of mass m, moves long the uniformly rough track PQR as shown in figure. The coefficient of friction, between the particle and the rough track equals mu . The particle is released, from rest from the point P and it comes to rest at a point R. The energies, lost by the ball, over the parts, PQ and QR, of the track, are equal to each other, and no energy is lost when particle changes direction from PQ to QR. The value of the coefficient of friction mu and the distance x (=QR) , are, respectively close to:

A particle is pulled along a curved surface very slowly. The coefficient of kinetic friction between the particle and surface is 0.4 . The heat generated during the pulling of the particle from the lowest point A to the topmost point B equals (The mass of the particle is 5 g )

A block A of mass m which is placed a rough inclined face of a wedge of same mass being pulled through light string and with force F as shown in figure The coefficient of friction between inclined face and block A is mu while there is no friction between the ground and wedge it the whole system moves with same acceleration then find the value of F

A long block A is at rest on a smooth horizontal surface. A small block B whose mass is half of mass of A is placed on A at one end and is given an initial velocity u as shown in figure. The coefficient of friction between the blocks is mu .

There block A B ,and C of equal mass m are placed one over the other on a frictionless surface (table) as shown in figure The coefficient of friction between any blocks A ,B and C is mu The maximum value of mass of block D so that the blocks A,B and C move without slipping over each other is

A cart of mass M has a block of mass m in contact with it as shown in the figure-2.133. The coefficient of friction between the block and the cart is mu . What is the minimum acceleration of the cart so that the block m does not fall ?