When force F applied on `m_(1)` and there is no friction between `m_(1)` and surface and the coefficient of friction between `m_(1)and m_(2)` is `mu.` What should be the minimum value of F so that there is on relative motion between `m_(1) and m_(2)`

When force F applied on m_(2) and there is no friction between m_(1) and surface and the coefficient of friction between m_(1) and m_(2) is mu… What should be the minimum value of F so that there is no relative motion between m_(1) and m_(2)

When force F applied on m_(1) and surface. Is mu_(1) and the coefficient of friction between m_(1) and m_(2) is mu_(2). What should be the minimum value of F so that there is no relative motion between m_(1) and m_(2).

In Fig. 7.150 , coefficient of friction between m_(2) and the horizontal surface is mu , minimum value of m so that the system has zero acceleration , is :

The coefficient of friction between m_(2) and inclined plane is mu (shown in the figure). If (m_(1))/(m_(2))=sin theta then

What force F must be applied so that m_(1) and m_(2) are at rest on m_(3) in

In the pulley arrangement shown in Fig the pulley p_(2) is movable .Assuming the coefficient of friction between m and surface to be mu the minimum value of M for which m is at rest is

The block each of mass 1 kg are placed as shown .They are connected by a string which passes over a smooth (massless) pulley. There is no friction between m_(1) and the ground.The coefficient of friction between m_(1) and m_(2) is 0.2 A force F is applied to m_(2) . Which of the fpllowing statement is/are correct?

In the figure , masses m_(1) , m_(2) and M are 20 kg , 5 kg and 50 kg respectively . The coefficient of friction between M and ground is zero . The coefficient of friction between m_(1) and M and that between m_(2) and ground is 0.4 . The pulleys and the string are massless . The string is perfectly horizontal between P_(1) and m_(1) and also between P_(2) and m_(2) . The string is perfectly vertical between P_(1) and P_(2) . An external horizonal force F is applied to the mass M . (Take g = 10 m //s^(2)) (a) Draw a free body diagram for mass M , clearly showing all the forces . (b) Let the magnitude of the force of friction between m_(1) and M be f_(1) and that between m_(2) and ground be f_(2) . For a particular F it is found that f_(1) = 2f_(2) . Find f_(1) and f_(2) . Write down equation of motion of all the masses . Find F , tension in the string and acceleration of the masses .