In the system shown in the figure, the string is light and coefficient of friction between the 10 kg block and the incline surface is `mu = 0.5`. Mass of the hanger, H is 0.5 kg. A boy places a block of mass m on the hanger and finds that the system does not move. What could be values of mass m?
`"tan"37^(@) = (3)/(4) "and" g = 10m//s^(2)`

In the arrangement shown in figure coefficient of friction between 5kg block and incline plane is mu=0.5 . Friction force acting on the 5kg block is

Block A of mass M in the system shown in the figure slides down the incline at a constant speed. The coefficient of friction between block A and the surface is 1 3 3 . The mass of block B is-

In Fig . 7.151 , coefficient of kinetic friction between the 4 kg block and the inclined surface is (1)/(sqrt3) . Here 'm' is such a mass that the 4 kg block is moving up the plane with a constant speed , then m is :

In the system show in figure, mass of the block placed on horizontal surface is M = 4 kg. A constant horizontal force of F = 40 N is applied on it as shown. The coefficient of friction between the blocks and surfaces is mu = 0.5 . Calculate the values of mass m of the block on the incline for which the system does not move . ["sin" 37^(@) = (3)/(5), g = 10 m//s^(2)]

Coefficient of friction between block of mass m and fixed wedge is mu = 0.5 . For what value of (m)/(M) frictional force between block of mass m and wedge becomes zero ?

In the figure shown, if friction coefficient of block 1 kg and 2kg with inclined plane is mu_(1) = 0.5 and mu_(2) = 0.4 respectively, then

The block A in the given figure is of mass 10sqrt(3) kg The coefficient of friction between the block and the surface on which it rests is 0.5. Find maximum mass of block B possible such that the system will be in equilibrium is.

A block is kept on a rough horizontal surface as shown. Its mass is 2 kg and coefficient of friction between block and surface (mu)=0.5. A horizontal force F is acting on the block. When