What does the scale read when two 100N weights are attached to a spring scale?

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When two 100N weights are attached to a spring scale, the scale reads 100N, not 200N, because the system is in static equilibrium. Each weight exerts a force of 100N, but the scale measures the tension force, which is equivalent to the force exerted by one weight when the other is present. This is similar to a scenario where one end of the scale is fixed to a wall; the wall provides a reaction force equal to the weight being measured. Understanding this concept involves recognizing that the second weight effectively replaces the wall in terms of force dynamics. The key takeaway is that the scale measures the tension in equilibrium, resulting in a reading of 100N.
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Homework Statement



http://img131.imageshack.us/img131/2996/physicswb9.th.png

Two 100N weights are attached to a spring scale as shown. What does the scale read?


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The Attempt at a Solution



This concept is difficult for me to grasp. My natural instinct would suggest that the scale would read 200N, but I know this can't be right.

What I know (or think I know) is that the system is in static equilibrium with ΣF=0. The weight force of the block on the left is 100N, same for the block on the right. Now I notice that if I were to remove one of the blocks, say the left one, and tie the loose end to a wall, the solution becomes obvious, the scale would read 100N.

I know the answer is 100N. What I don't know is why the answer is 100N. There is a fundamental concept of Newton's laws that I am not getting here. Specifically Newton's third law. Can someone please explain this to me as if I were a 2 year old, with big colourful pictures preferably drawn in crayon?
 
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First we have to make clear what the reading on the spring scale means. It means the current tension force in the spring scale.

So, I would say that the "reading" of the scale in this "situation" will be the same in the usual situation where one end of the scale is fixed on a wall. The two situations are equivalent, as you already proved in your analysis; each scale in each situation is in equilibrium.
 
Yes, the second block essentially 'replaces' the wall as far as forces are concerned. You can see this quite easily if you sketch a quick force diagram; The 100N the extra block exerts on the spring, is the same 100N which would be excerted by a wall, if the spring were attached to a wall.

For the spring scale to work, it ofcourse has to be in equilibrium (otherwise it would accalerate and won't measure the correct weight). A wall simply provides a reaction force equal to the weight exerted by the object to be measured.

(Another consequence of this is, that when you tie something to the wall and pull it, you can pull it just as hard as when you replace the wall with a second person who pulls as hard as you. If you understand this, you'll also understand the spring-scale problem)
 
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wololoh said:
Yes, the second block essentially 'replaces' the wall as far as forces are concerned. You can see this quite easily if you sketch a quick force diagram; The 100N the extra block exerts on the spring, is the same 100N which would be excerted by a wall, if the spring were attached to a wall.

For the spring scale to work, it ofcourse has to be in equilibrium (otherwise it would accalerate and won't measure the correct weight). A wall simply provides a reaction force equal to the weight exerted by the object to be measured.

(Another consequence of this is, that when you tie something to the wall and pull it, you can pull it just as hard as when you replace the wall with a second person who pulls as hard as you. If you understand this, you'll also understand the spring-scale problem)

Thank you, the solution is clear now.
 

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