Piston: Difference between revisions

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These steps can be done differently and the processes can become very complex, however this is a simple example of how a piston can be made to perform useful work through the input of heat. It is known that this heat cannot be transformed fully into work, otherwise the [[entropy]] of the system would decrease which is forbidden by the [[Second law of thermodynamics]].  
These steps can be done differently and the processes can become very complex, however this is a simple example of how a piston can be made to perform useful work through the input of heat. It is known that this heat cannot be transformed fully into work, otherwise the [[entropy]] of the system would decrease which is forbidden by the [[Second law of thermodynamics]].  
==References==
{{reflist}}
[[Category:Uploaded]]


==For Further Reading==
==For Further Reading==
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*[[First law of thermodynamics]]
*[[First law of thermodynamics]]
*Or explore a [[http://energyeducation.ca/encyclopedia/Special:Random| random page]]
*Or explore a [[http://energyeducation.ca/encyclopedia/Special:Random| random page]]
==References==
{{reflist}}
[[Category:Uploaded]]

Revision as of 17:20, 25 June 2026

Figure 1: A piston contained inside of a cylinder, used within a sectioned gasoline engine.[1]

A piston is a moving disk enclosed in a cylinder which is made gas-tight by piston rings. The disk moves inside the cylinder as a liquid or gas inside the cylinder expands and contracts. A piston aids in the transformation of heat energy into mechanical work and vice versa. Because of this, pistons are a key component of heat engines.[2] Pistons work by transferring the force output of an expanding gas in the cylinder to a crankshaft, which provides rotational momentum to a flywheel. Such a system is known as a reciprocating engine.

A piston must follow a cyclical process in order for it to continuously convert heat energy to work, and there are many ways to complete this cycle. For example:

  1. By inputting heat to the gas inside the cylinder, the gas will expand increasing the volume in the cylinder and provide useful work.
  2. By removing heat from the cylinder, the gas's pressure will decrease, allowing it to be compressed more easily.
  3. By inputting work to the piston, the piston will compress back to its initial state, ready to perform the cycle once again.

This cycle can be visualized in Figure 2 below.

Figure 2: An example of a piston cycle, in which it manipulates heat in order to perform useful work.[3]

These steps can be done differently and the processes can become very complex, however this is a simple example of how a piston can be made to perform useful work through the input of heat. It is known that this heat cannot be transformed fully into work, otherwise the entropy of the system would decrease which is forbidden by the Second law of thermodynamics.

For Further Reading

References

  1. Wikimedia Commons [Online], Available: http://upload.wikimedia.org/wikipedia/commons/7/75/Piston_of_DAT_engine.jpg
  2. R. D. Knight, "Heat Engines and Refrigerators" in Physics for Scientists and Engineers: A Strategic Approach, 3nd ed. San Francisco, U.S.A.: Pearson Addison-Wesley, 2008, ch.19, sec.2, pp.530
  3. Adapted from Physics for Scientists and Engineers by R. Knight