In the figure, `m_(A) = 2kg`, and `m_(B) = 4 kg`. For what minimum value of force F, A starts slipping over B `(g = 10 ms^(-2))`

In the figure, m_(A)=2 kg and m_(B)=4kg . For what minimum value of F,A starts slipping over B? (g=10m//s^(2))

In the figure, m_(A)=2 kg and m_(B)=4kg . For what minimum value of F,A starts slipping over B? (g=10m//s^(2))

Initially, both the blocks are at rest on horizontal surface as shown in the figure. Find the minimum value of force F in (N) so that sliding starts between the blocks (g=10ms^(-2))

A force F is acting at an angle theta with horizontal on a block of mass 12 kg placed on a rough 3 horizontal surface having coefficient of friction mu=3/ 4 as shown in the figure. The minimum value of force F to just move the block will be (g = 10 ms^-2)

In the figure shown, m_(1) = 10kg, m_(2) = 6kg, m_(3) = 4kg. If T_(3) = 40 N, T_(2) = ?

find minimum value of F such that m_(2) starts its motion on the ground

A force F is acting at an angle theta with horizontal on a block of mass 12 kg placed on a rough horizontal surface having coefficient of friction mu=frac{3}{4} as shown in the figure. The minimum value of force F to just move the block will be ( g = 10 ms^-2 )

In figure m_(1)= 1 kg and m_(2)= 4 kg Find the mass m of the hanging block which will prevent the smaller block from slipping over the triangular block .All the surface are frictionless and the string and the pulleys are light

In the figure shown m_(1) = 1 kg , m_(2) = 2 kg , pulley is ideal . At t = 0 , both msses touches the ground and string is tout . A force F = 2t is applied to pulley ( t is in second ) then m_(1) is lifted off the ground at time ( g = 10 m//s^(2))

Figure shows a system of four pulleys with two masses m_(A) =3kg and m_(B)=4 kg . At an instant force acting on block A if block B is going up at an acceleration of 3 m//s^(2) and pulley Q is going down at an acceleration of 1 m//s^(2) is .