Acceleration of the end of a hinged rod in a pulley system

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Discussion Overview

The discussion revolves around the dynamics of a hinged rod in a pulley system, focusing on the acceleration of the end of the rod. Participants explore the equations of motion, moments of inertia, and relationships between various forces and accelerations in the system. The context includes homework-related problem-solving and mathematical reasoning.

Discussion Character

  • Homework-related
  • Mathematical reasoning
  • Debate/contested

Main Points Raised

  • One participant suggests that solving the problem requires five simultaneous equations, while another believes four equations should suffice due to the number of variables.
  • There is a discussion about the sign convention used for moments, with a participant pointing out a potential sign issue in the equations.
  • Participants discuss the relationship between the tangential acceleration of point B and the acceleration of block A, suggesting that this relationship could provide an additional equation.
  • One participant proposes that the acceleration of block A is equal to the negative of the tangential acceleration of point B, raising questions about the validity of this approach.
  • Another participant asserts that the magnitudes of tangential accelerations of points A and B should be equal due to the inextensibility of the connecting string.
  • Participants share their calculated values for radial and tangential accelerations, noting discrepancies with expected results.
  • One participant expresses uncertainty about the correctness of their calculations, indicating that they are working from an online task without a known correct answer.

Areas of Agreement / Disagreement

Participants exhibit disagreement regarding the number of equations needed and the relationships between the variables. There is no consensus on the correct approach to derive the necessary equations or the accuracy of the calculated accelerations.

Contextual Notes

Participants mention potential sign issues and the need for additional equations, indicating that assumptions about the system's configuration and the definitions of variables may be influencing their reasoning. The discussion remains open-ended with unresolved mathematical steps.

deusy
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Homework Statement


As shown in image.
Screen Shot 2016-10-26 at 10.25.02 PM.png


2. Homework Equations
Moment of inertia of pulley = [tex]1/2*M*R^2[/tex]
Moment of inertia of rod (about end) = [tex]1/3*M*L^2[/tex]
Acceleration of end of rod in theta direction = [tex]L*α[/tex]
Acceleration of end of rod in radial direction = [tex]L*ω^2[/tex]

The Attempt at a Solution


Pretty sure this question requires solving a system of five simultaneous equations, but I cannot work out the final one.

Note:
T1 = tension of rope attached to A
T2 = tension of rope attached to B
M = mass
R = radius
α = angular acceleration
ω = angular velocity
Positive movement defined upwards

From free body diagram of block A:

[tex]T1- M(A)*g = M(A)*a(A)[/tex]

From taking the moment around the pulley:

[tex]T1*R(pulley)-T2*R(pulley)=I(pulley)*α(pulley)=1/2*M(pulley)*R(pulley)^2*α(pulley)[/tex]

From taking the moment around the rod:

[tex]T2*L-M(rod)*g*L/2=I(rod)*α(rod)=1/3*M(rod)*L^2*α(rod)[/tex]

From polar coordinates:

[tex]a(A) = -R(pulley)*α(pulley)[/tex]

One equation missing

Once I work out the last equation and solve for α(rod), I should be able to use Pythagoras to work out the magnitude of the acceleration from:

[tex]a=((α(rod)*L)^{2}+((L*ω^2)^{2}))^{1/2}[/tex]

Can anyone see what I'm missing and/or if I'm going wrong in any of the other equations? Been trying this question for hours and can't get my head around it.
 
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deusy said:
Pretty sure this question requires solving a system of five simultaneous equations, but I cannot work out the final one.

I think there are only four variables so four equations should be enough .

deusy said:
From taking the moment around the rod:

[tex]T2*L-M(rod)*g*L/2=I(rod)*α(rod)=1/3*M(rod)*L^2*α(rod)[/tex]

I guess you have considered anticlockwise positive , in which case you have a sign issue .

Apart from that everything else looks fine :smile: . I hope I am not overlooking something.
 
Vibhor said:
I think there are only four variables so four equations should be enough.
There's five in my equations, unless one I can work out from something else?:
[tex]a(A), T1, T2, <br /> α(rod), α(pulley) ?[/tex]
Otherwise I think I still need a fifth equation.

Thanks for the sign tip, though!
 
deusy said:
There's five in my equations, unless one I can work out from something else?:
[tex]a(A), T1, T2,<br /> α(rod), α(pulley) ?[/tex]
Otherwise I think I still need a fifth equation.

OK .Fair enough .

The tangential acceleration of point B is related to the acceleration of the block .
 
Vibhor said:
The tangential acceleration of point B is related to the acceleration of the block .

Are you implying there's another equation I can get from this?
 
deusy said:
Are you implying there's another equation I can get from this?

Yes .

Replace the rod attached to point B with a mass M .

How would acceleration of block A and mass M be related ?
 
Last edited:
Vibhor said:
How would acceleration of block A and mass M be related ?

Would it be that:
[tex]a(A)=-a(B[tangential]) = -L*ω^{2}[/tex]

As the displacement of A is the negative displacement of B (if considering it B as mass), so [tex]a(A)=-a(B)[/tex] in the tangential direction? This allows me to calculate a(A) without solving simultaneously, which doesn't seem right to me.
 
Yes . The magnitude of tangential acceleration of B should be equal to that of A as they are connected by an inextensible string .

This should give you the answer .

What values are you getting for tangential and radial acceleration of B ?
 
Vibhor said:
Yes . The magnitude of tangential acceleration of B should be equal to that of A as they are connected by an inextensible string .

This should give you the answer .

What values are you getting for tangential and radial acceleration of B ?

I am getting:
[tex]a[radial]=7.677 m/s/s[/tex]
[tex]a[tangential] = 6.728 m/s/s[/tex]

(magnitudes only)

These are not giving me the correct answer for overall acceleration.
 
Last edited:
  • #10
What is the given correct answer ?
 
  • #11
Vibhor said:
What is the given correct answer ?

I won't know it until I get it right unfortunately, this is a question from an online task.
 
  • #12
I am getting 8.938 m/s2 as magnitude of tangential acceleration .
 
  • #13
Vibhor said:
I am getting 8.938 m/s2 as magnitude of tangential acceleration .

I am just doing:
[tex]0.8*2.9^2=6.728[/tex]
 
  • #14
deusy said:
I am just doing:
[tex]0.8*2.9^2=6.728[/tex]

This is radial acceleration .
 

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