Find an expression for the acceleration

AI Thread Summary
The discussion focuses on deriving an expression for the acceleration of mass m_1 in a pulley system involving two masses, m_1 and m_2. Participants clarify the effects of friction and the relationship between the accelerations of the two masses, noting that a_2 is half of a_1. The equations of motion for both masses are established, emphasizing the importance of consistent sign conventions. After addressing initial misunderstandings, a correct expression for a_1 is derived as a_1 = (2*m_2*g)/(4m_1+m_2). The final result is confirmed as accurate by the participants.
aliciaw0
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In the figure, find an expression for the acceleration of m_1

i don't understand why

(-m_2*g)/(((-m_2)/2)-m_1) isn't right

because the a of mass#2 is (-a_1)/2 right?
 

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So i am assuming that the pulley has no friction and its rotation does not need to be taken into account, also the pulley does has no mass and can be treated as a point particle.

Just draw a FBD for each mass seperately.

The first mass has friction f with the table (i assume this, if it is not the case than f =0 ofcourse). T is the tension in he rope
m_1a_1 = T-f

For mass 2 you get
m_2a_2=2T-m_2g

hence m_1 = \frac{m_2(a_2+g)-2f}{2a_1}

This is the most general form. I do not know whether extra info was given on the masses standing still or not ? If so, some variables in the above formula will vanish

marlon
 
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oh that's right, it never did say anything about it being frictionless, maybe that's what i did wrong.

and there was no other information about the masses standing still
 
aliciaw0 said:
i don't understand why

(-m_2*g)/(((-m_2)/2)-m_1) isn't right
Show how you arrived at this answer.

because the a of mass#2 is (-a_1)/2 right?
That's correct. (Be careful with signs.)
 
x m_1: T=m_1*a_1

y m_2: T-m_2*g=m_2*a_2
2(m_1*a_1)*g=m_2*a_2

a_2= a_1/2

2 (m_1*a_1)*g=m_2*(a_1/2)
 
aliciaw0 said:
x m_1: T=m_1*a_1
OK.
y m_2: T-m_2*g=m_2*a_2
Two problems here:
(1) The rope pulls twice on the pulley (and thus on m_2)
(2) Careful with your sign convention. If you want to use up for positive, then be consistent. (You chose a positive a_1 going to the right.)

a_2= a_1/2
If m_1 moves to the right, then m_2 moves down: this means that if you call a_1 positive, then by your sign convention for m_2, its acceleration should be negative a_2.

Regarding sign conventions, here's what I do: I always assume a_1 and a_2 to be positive numbers. I also visualize how the accelerations relate to each other. If a_1 is to the right, then a_2 is down. Then I write my equations accordingly.

Try it again.
 
oh ok.. so i redid it and i got

m2 y: 2T-m_2*g=m_2*a_2

since T= m_1*a_1 i subsituted that it and solved for a_1 and got

a_1= (2*m_2*g)/(4m_1+m_2) is this right?
 
Looks good to me.
 

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