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 block $A$ and $B$ is $0.4$ . The maximum horizontal force $F$ that can be applied so that block $A$ does not slip over the block $B$ ( $g = 10 m / s^{2}$ ) is

25 N

No worries! We‘ve got your back. Try BYJU‘S free classes today!

20 N

Right on! Give the BNAT exam to get a 100% scholarship for BYJUS courses

30 N

No worries! We‘ve got your back. Try BYJU‘S free classes today!

40 N

No worries! We‘ve got your back. Try BYJU‘S free classes today!

Open in App

Solution

The correct option is B $20 N$
Net horizontal force due to tension in the string on block $B$ is zero. Hence, the given figure (a) can be replaced by figure (b).

Maximum value of friction $f_{m a x} = μ m_{A} g = 0.5 \times 2 \times 10 = 10 N$

Block $B$ moves due to friction alone. Therefore, maximum common acceleration of the two blocks can be
$a_{m a x} = \frac{f_{m a x}}{m_{B}} = \frac{10}{2} = 5 m/s^{2}$

But $a_{m a x} = \frac{F_{m a x}}{m_{A} + m_{B}}$
$\Rightarrow F_{m a x} = (m_{A} + m_{B}) a_{m a x} = 4 \times 5 = 20 N$

Suggest Corrections

Similar questions

In the arrangement shown in ﬁgure $m_{A} = m_{B} = 2 k g$ . 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 $μ = 0.5$ . What maximum horizontal force F can be applied so that block A does not slip over the block B? $(g = 10 m / s^{2})$