Dynamics involving dependent motion

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The discussion focuses on the relationship between the velocities of cylinders A, B, and C, with a specific emphasis on calculating the acceleration of A when t = 2 seconds. The velocity of cylinder B is given by vB = t^2/2 + t^3/6, and the relationship between the velocities is established as vB = -2vA, indicating that as A moves down, B moves downward at twice the speed of A. The positions of B and C are expressed in terms of each other, leading to the conclusion that yB = 2yC - L, where L is the constant length of the rope. The analysis shows that the motion of A and C is inversely related, with vA = -vC. The thread concludes with the calculation of the acceleration of A based on these relationships.
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If cylinder B has a downward velocity in feet per second given by
vB = t2/2 + t3/6 , where t is in seconds. Calculate the acceleration of A
when t = 2 seconds.

How does the velocities of A & B relate...Seems to be at C but I am not clear how to state it.
 

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If you just look at A and C, you should see that vA=-vC. In other words, A and C move at the same speed and when A moves down, C moves up (and vice versa).

You might be able to see the relationship between B and see, but let's try it a little more analytically: Let's call yC the position of C and yB the position of B. Now let's write yB as a function of yC:

y_B=y_c - x

where x is a variable I just made up to represent the length of rope between the pulley and weight B. But the length of the rope (let's call it L) is constant and equal to L=yC-x

Plug this into the equation for yB:

y_B=y_C - (L - y_C)
y_B = 2y_C - L

Take the derivative to find the relationship between velocities (remember L is constant):

v_B=2v_C

with

v_C=-v_A

so

v_B=-2v_A
 
Thanks, I finally arrived at this answer Thursday.
 
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