Two blocks are connected over a massless pulley as shown in figure. The mass of block A is 10 kg and the coefficient of kinetic friction is 0.2 Block A sliders down the incline at constant speed. The mass of block B in kg is

A block of mass m moves with constant speed down the inclined plane of inclination theta . Find the coefficient of kinetic friction.

A block with mass m_(1) is placed on an inclined plane with slope angle alpha and is connected to a second hunging block with mass m_(2) by a cord passing over a small . Friction less pulley as shown in fig 7.247 . The coefficient of static friction is mu_(2) and the coefficient of kinetic friction is mu_(s) a. Find the mass m_(2) for which block m_(1) moves up plane at constant speed once it is set in motion b. Find the mass m_(2) for which block m_(1) moves down the plane at constant speed once it is set in motion c.For what range of m_(2) will the blocks remain at rest if they are released from rest?

Two blocks of equal masses are connected by an ideal string passing over an ideal pulley as shown in the figure All the surfaces in contact with blocks are rough having coefficient of kinetic friction mu between them. If the blocks slide with constant velocity, find the value of mu

Two blocks A and B of respective masses 6 kg and 4 kg are connected with a string passing over a light friction less pulley as shown in the figure . The coefficient of friction between the block A and horizontal surface is 0.4 . Then the minimum mass of block C which should be placed over A to prevent it from moving is :

A block B is pulled by a force of 18 N applied to a light pulley as shown in the figure. If the coefficient of friction is 0.4 and the acceleration of the block is 0.5 ms^(-2) , the mass of the block is (g = 10 m//s^2)

Two blocks A & B are connected by a light inextensible string passing over a fixed smooth pulley as shown in the figure. The coefficient of friction between the block A and the horizontal table is mu=0.2 . If the block A is just to slip, find the ratio of the masses of the blocks.

A body of mass 20kg is moving on a rough horizontal plane. A block of mass 3kg is connected to the 20 kg mass by a string of negligible mass through a smooth pulley as shown in the figure. The tension in the string is 27 N. The coefficient of kinetic friction between the heavier mass and the surface is (g = 10m/ s^2 )

A block 'P' of mass 5kg is placed on a block 'Q' of mass 10kg which is placed on a smooth surface and both blocks are connected with a light string which is passing over an ideal pulley as shown as in figure.Force of magnitude 10N is applied on the block and coefficient of friction between the blocks in 0.4 .The tension in the string will be

Two blocks A and B are connected by a string as shown as shown in the figure . Friction coefficient of the inclined plane is 0.5 . The mass of the block A is 5 kg. If minimum and maximum values of mass of the block B for which the block A remains in equilibrium are m_(1) and m_(2) then find the value of (m_(2) - m_(1)) [in kg]

A trolley of mass 20 kg is attached to a block of mass 4kg by massless string passing over a frictionless pulley as shown in the figure. If the coefficient of kinetic friction between trolley and the surface is 0.02, then the accderal ion of the trolley and block system is ("Take" g=10ms^(-2))