What moves the piston in a Carnot heat engine?

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Discussion Overview

The discussion revolves around the mechanics of how a piston moves in a Carnot heat engine, exploring the underlying principles of entropy and work. Participants examine various models and explanations related to the expansion and compression phases of the engine cycle.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • One participant questions the mechanics of piston movement, noting discrepancies in diagrams showing different methods of control, such as removing weights versus a wheel attachment.
  • Another participant states that expanding gas is responsible for moving the piston during the high-pressure phase, while something else must return it during the low-pressure phase.
  • It is mentioned that the Carnot cycle is theoretical and no real cycles achieve its predictions.
  • A participant explains that reversible work requires gradual changes in force applied by the piston, with examples of lifting weights and using a wheel to illustrate this concept.
  • Further discussion highlights that the work done during expansion can be offset by the work required for compression, raising questions about the net work done in the cycle.
  • Another participant emphasizes that the amounts of weights added and removed during the expansion and compression phases do not match, indicating a net amount of work is done.

Areas of Agreement / Disagreement

Participants express differing views on the mechanics of the piston movement and the implications of work done during the Carnot cycle. There is no consensus on a singular explanation, and the discussion remains unresolved regarding the specifics of how work is managed in the cycle.

Contextual Notes

Participants acknowledge the theoretical nature of the Carnot cycle and the complexities involved in achieving reversible processes, which may depend on specific conditions and definitions not fully explored in the discussion.

trigger701
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Hi everyone,

I have been looking at Carnot heat engines in a bid to better understand entropy, and I can't figure out how it actually does work. Why does the piston move?

In some diagrams I have seen weights being removed from the piston, reducing the pressure at constant temperature and therefore causing expansion. In other diagrams however, the piston is attached to a wheel and the expansion seems to just happen.

Can anybody help me understand why the piston is actually moving? And if it is due to external control of the piston, then surely this would require work- does this not defeat the object?

Trigger
 
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trigger701 said:
Why does the piston move?

Expanding gas.
 
In the high pressure phase, the expanding gas moves the piston. In the low pressure phase, something else must move the piston back. That is often done with inertia from a flywheel or with a crank shaft connection to another piston that is in the high pressure phase. The greater the pressure difference between the high and low pressure phases, the more work can be extracted from the machine.
 
Last edited:
you should realize that a Carnot cycle is a theoretical, ideal cycle. There are no cycles that achieve the Carnot predictions.
 
The ideal Carnot cycle consists of reversible expansions and compressions, both isothermal and adiabatic. To do work reversibly during the expansion phases, the force applied by the piston has to be decreased very gradually. Your example of removing tiny weights from the piston is one way of doing this. In the case of removing tiny weights, the piston is rising, and the weights are thus being lifted and delivered to a series of higher elevations. This work on the weights increases their potential energy. But adding and removing tiny weights is not the only way that reversible work can be done by the working fluid. In the case of a piston attached to a wheel, the force applied by the wheel must also be decreasing gradually in order for the work being done on it to be reversible. So the examples you have seen in books are just different ways of making the work done in the cycle to be reversible. Remember that a reversible process is one in which the system is only slightly removed from being in thermodynamic equilibrium throughout the change. So, a reversible process can be regarded as a continuous sequence of thermodynamic equilibrium states of the system. This can be achieved by making sure that the force applied by the system is never more than slightly different from that of the entity that it is doing work on or receiving work from.
 
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Chestermiller said:
In the case of removing tiny weights, the piston is rising, and the weights are thus being lifted and delivered to a series of higher elevations. This work on the weights increases their potential energy.

Thank you very much Chestermiller, a very helpful response.

So would you say that the weights lifted can in theory just be put back on to the piston to do the work necessary for the compression phases, and this means that you are offsetting the work required to lift the weights in the first place? You are still, therefore, doing overall useful work during the expansion.
 
trigger701 said:
Thank you very much Chestermiller, a very helpful response.

So would you say that the weights lifted can in theory just be put back on to the piston to do the work necessary for the compression phases, and this means that you are offsetting the work required to lift the weights in the first place? You are still, therefore, doing overall useful work during the expansion.
The amounts that you put on at the various elevations during the compression phases do not match the amounts you take off during the expansion phases. We know this because a net amount of work is done.
 
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Chestermiller said:
The amounts that you put on at the various elevations during the compression phases do not match the amounts you take off during the expansion phases. We know this because a net amount of work is done.

Thank you, this alleviates my confusion. I'm glad I asked.
 

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