Work of spring vs force of spring?

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Discussion Overview

The discussion revolves around the relationship between the work done by a mass (sand) and the compression of a spring, specifically whether to apply Hooke's law or the work-energy principle in this context. Participants explore the theoretical implications of both approaches in calculating the compression of the spring under different scenarios, including gravitational effects.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant suggests using the work-energy principle, stating that the work done by the sand (mgy) should equal the potential energy stored in the spring (kx^2/2).
  • Another participant agrees with the use of kx^2/2, framing it in terms of energy conversion from gravitational potential energy to spring potential energy.
  • Some participants express confusion over the use of Hooke's law versus the work-energy approach, noting that different sources provide varying methods for solving similar problems.
  • One participant proposes that both methods could be valid, depending on the scenario, but raises concerns about the consistency of results from each approach.
  • Another participant emphasizes that the force exerted by the spring varies with compression, suggesting that the work-energy approach is more appropriate for calculating compression when a constant force is applied.
  • There is mention of using conservation of energy principles to determine the speed of a mass at the end of a spring, indicating a broader application of energy concepts in this context.

Areas of Agreement / Disagreement

Participants do not reach a consensus on whether to use Hooke's law or the work-energy principle for calculating spring compression. Multiple competing views remain regarding the applicability of each method, and the discussion reflects uncertainty about the correct approach.

Contextual Notes

Participants note that the force exerted by the spring changes with compression, which complicates the application of Hooke's law in certain scenarios. There are unresolved questions about the assumptions underlying each method and how they apply to different configurations of the problem.

kahwawashay1
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Let's say you have a hydraulic lever. On the end with the smaller area, you want to slowly pour sand, so as to compress a spring on the other end, which has the bigger area. If you want to find how much mass of sand is needed to compress this spring a certain distance, would you use Hooke's law or W=kx^2/2 ?

My reasoning is that you would say kx^2/2=mgy, where y is the vertical displacement of the smaller piston, so mgy is the work done by the sand, and since "the work done on the input piston by the applied force is equal to the work done by the output piston in lifting the load placed on it" (according to my book), then mgy must equal kx^2/2.

Is this right?
 
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I believe you are correct.

Instead of work, you can also think of it in terms of potentials (which are very similar). The potential energy lost by the sand moving down in the gravitational field must go somewhere, and if the spring is compressing, the energy is being converted from gravitational potential energy to spring potential. So I think you are correct when you use kx^2/2, because this is the potential of the spring (The potential of a spring is the force integrated over x)
 
khemist said:
I believe you are correct.

Instead of work, you can also think of it in terms of potentials (which are very similar). The potential energy lost by the sand moving down in the gravitational field must go somewhere, and if the spring is compressing, the energy is being converted from gravitational potential energy to spring potential. So I think you are correct when you use kx^2/2, because this is the potential of the spring (The potential of a spring is the force integrated over x)

That's what I thought too but then I saw several solved problems like this one from various sources that used only Hooke's law, not integrating it...? So our reasoning must be wrong?
 
Hmm...

If we were to drop sand on a spring directly, the amount it would compress would come from the force diagrams I think... So if I drew my spring on a table, and I put sand on top, it would compress an amount mg/k. However, one might be able to use energy. If I have a mass at the top of the spring, and I drop it, and the mass drops a distance x, than the gravitational energy lost by the mass is mgx, while the energy gained in the spring would be kx^2/x.

I think you can use both methods.
 
khemist said:
Hmm...

If we were to drop sand on a spring directly, the amount it would compress would come from the force diagrams I think... So if I drew my spring on a table, and I put sand on top, it would compress an amount mg/k. However, one might be able to use energy. If I have a mass at the top of the spring, and I drop it, and the mass drops a distance x, than the gravitational energy lost by the mass is mgx, while the energy gained in the spring would be kx^2/x.

I think you can use both methods.

Im quite sure you cannot just use both methods since they do not lead to the same answers...

and I think in the example you mentioned you would use work, not Hooke's law. If you put sand on top of your spring, you would use mgy=kx^2/2, because the force from the sand stays constant, but the force needed to compress the spring varies. So at first, the spring will compress more easily than towards the end..

I mean obviously you cannot use both ways since one way leads to x=[itex]\sqrt{2mgy/k}[/itex]
while the other leads to x=mg/k

Hooke's Law I think would apply to something like the following: Let's say we know that once the sand fully compresses the spring, the force the spring exerts upwards towards the sand is 10 N. Then we can find how much the spring has been compressed from its equilibrium point by x=10/k ...
 
You might be right. I know that if we want to determine the speed of a mass at the end of a spring we would need to use conservation of energy, and the kx^2/2, but I guess if you wanted to find the amount of mass that will compress the spring a particular distance you could use F=ma equations.
 

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