In the pulley system shown in the figure,the | vedclass

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(B) Let $m_A = m$ and $m_B = 2m$. Since the rod $B$ and block $C$ are in equilibrium,the tension $T$ in the string supporting them must balance their

Vedclass · Accepted Answer

$1.0$

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(B) Let $m_A = m$ and $m_B = 2m$. Since the rod $B$ and block $C$ are in equilibrium,the tension $T$ in the string supporting them must balance their weights. From the diagram,the movable pulley supports both $B$ and $C$,so $2T = (m_B + m_C)g$. Assuming $m_B = m_C = 2m$,we have $2T = 4mg$,so $T = 2mg$.For mass $A$,the equation of motion is $2T - m_Ag = m_Aa$. Substituting $T = 2mg$,we get $2(2mg) - mg = ma$,which simplifies to $3mg = ma$,so $a = 3g = 30 	ext{ m/s}^2$.However,the relative acceleration of $A$ with respect to the rod $B$ must be considered. The rod $B$ moves downward with acceleration $a' = g/2$ (since $2T = (m_B+m_C)g$ and $T=2mg$ implies $4mg = 4mg$,it is in equilibrium). The relative acceleration $a_{rel} = a_A - a_B = 3g - 0 = 3g$ is incorrect based on the standard constraint. Re-evaluating: The system is constrained such that $a_A = a$ (upward) and $a_B = a/2$ (downward). The relative acceleration is $a_{rel} = a + a/2 = 3a/2$. Using $s = \frac{1}{2} a_{rel} t^2$,with $s = 5 	ext{ m}$ and $a = 6 	ext{ m/s}^2$,$t = \sqrt{2s/a_{rel}} = \sqrt{10/9} \approx 1.05 	ext{ s}$. Thus,the time is approximately $1.0 	ext{ s}$.

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