Two blocks A and B are shown in figure. The minimum horizontal force F applied on Blocks B for which slipping begins at B and ground is

Two block A and B are as shown in figure. The minimum horizantal force F applied to the block B for which slipping begins between B and ground is :

Two blocks A and B are as shown in figure. The minimum horizontal force F applied to the block B for which slipping behins between B and ground is :

The system of two blocks is at rest an shown in the figure. A variable Horizontal force is applied to the upper block. The maximum possible constant force exerted by the horizontal ground surface on the lower block is ( coefficient of friction for both the contracts is mu )

In the previous problem. The friction force applied by ground on block B is

In the arrangement shown in figure m_(A)=m_(B) =2 kg . String is massless and pulley is frictionless. Block B is resting on a smooth horizontal surface, while friction coefficient between blocks A and B is mu=0.5 . What maximum horizontal force F can be applied so that block A does not slip over the block B? (g=10 m//s^(2))

Two blocks A and B of masses 2kg and 4kg are placed one over the other as shown in figure. A time varying horizontal force F =2t is applied on the upper block as shown in figure. Here t is in second and F is in newton. Drow a graph showing acceleration of A and B on y-axis and time on x-axis.Coefficient of friction between A and B is mu =(1)/(2) and the horizontal surface over which B is placed smooth. (g =10m//s^(2))

Two blocks A and B are placed in contace on a horizontal surface. Faces of block A and B , which are in contact , are inclined at 30^(@) with the horizontal, as shown. There is no friction between block A and any surface which is in contact with this whereas friction coefficient between block B and the surface is (1)/(sqrt(3)) . A force F is applied in horizontal direction on block A . What is the minimum value of F at which the block B just start moving rightwards ?

Block B of mass 2kg rests on block A of mass 10kg . All surfaces are rought with the value of coefficient of friction as shown in the figure. Find the minimum force F that should be applied on block A to cause relative motion between A and B . (g=10m//s^(2))

In the arrangement shown in figure, m_A = m_B = 2kg. String is massless and pulley is frictionless. Block B is resting on a smooth horizontal surface, while friction coefficient beteen block A and B is mu=0.5 . the Maximum horizontal force F that can be applied so that block A does not slip over block B is.

Two blocks A and B each of mass m are placed on a smooth horizontal surface. Two horizontal force F and 2F are applied on blocks A and B, respectively, as shown in fig. Block A does not slide on block B. Then then the normal reaction acting between the two blocks is (assume no friction between the blocks)