Compress Air to Liquid - Is it Possible?

In summary, when compressed air is turned into liquid, the temperature of the air decreases without any influence from the person compressing the air.
  • #1
bozo the clown
93
0
If i compress air enough without altering temparature it will turn to liquid right ?
 
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  • #2
Yes, but air is not a pure substance. The various gases (nitrogen, oxygen, argon, carbon dioxide, water vapor, etc.) will all condense at different pressures.

- Warren
 
  • #3
Do the gases that make up our air, when compressed, have a tendency to seperate, gather, form layers, etc. in some particular way?
 
  • #4
not in gas form, in liquid form, they probably will form layers since they all have different densities
 
  • #5
And by the way, for your original question, as you decrease volume (compress), the temperature drops without you having any influence on it except compresing it.
P_1/T_1=P_2/T_2
 
Last edited:
  • #6
ArmoSkater87 said:
And by the way, for your original question, as you decrease volume (compress), the temperature drops without you having any influence on it except compresing it.
[hex] P_1/T_1 = P_2/T_2 [/hex]

Don't you have that backward? I believe temperature increases as a gass (or an assortment of gasses) is compressed.
 
  • #7
temperature of the air increases as the volume of the container decreases because the molecules would be traveling faster and bouncing off the sides of the container more frequently.
brownian motion
 
  • #8
yea...ur right i don't know what i was thinking, i though of it backwards :D
 
  • #9
does the energy required to compress the air ( say for arguments sake oxygen ) to turn to liquid = the energy required to turn to liquid using temperature alteration
 
  • #10
good question
 
  • #11
jamie said:
temperature of the air increases as the volume of the container decreases because the molecules would be traveling faster and bouncing off the sides of the container more frequently.
brownian motion

If the volume of the container decreases, then the inner surface area of the container decreases in which the molecules rebound. The mass of the molecules is consistent, why does the velocity increase when compression occurs? Shouldn't the velocity actually decrease, because of increased contact with the smaller surface area of the container increases which causes of loss of velocity to the container wall for every rebound a molecule makes? And wouldn't this result in a decrease in temperature?
 
  • #12
Your fundamental mistake is assuming that the gas particles always lose kinetic energy when they hit the walls of the container. They don't. If the walls of the container (say, the metal tank wall) is at the same temperature as the gas, then its molecules have similar kinetic energies. The only difference is that the wall's atoms/molecules are tightly bound to each other and vibrate back and forth rather than flying around freely. Sometimes a collision will transfer some kinetic energy from a gas particle to a particle in the wall; sometimes the opposite will happen. The net result is thermodynamic equilibrium.

If every collision resulted in the gas particle losing energy (and the wall particle gaining it), you'd find that the gas inside any container rapidly approaches absolute zero, while the temperature of the wall rapidly rises. It wouldn't make any sense.

- Warren
 

1. Can air be compressed into a liquid state?

Yes, it is possible to compress air into a liquid state. This process is known as liquefaction and it involves compressing air at a high pressure and then cooling it to a very low temperature.

2. What are the benefits of compressing air into a liquid state?

Compressing air into a liquid state allows for a much higher storage density compared to storing it as a gas. This makes it more efficient for transportation and storage. It also allows for easier handling and use in various applications.

3. How is air compressed into a liquid state?

Air can be compressed into a liquid state using a process called the Linde-Hampson cycle. This involves compressing air using a compressor, cooling it using a refrigerant, and then expanding it rapidly to lower its temperature and pressure, resulting in liquefaction.

4. What are some applications of compressed air in a liquid state?

Compressed air in a liquid state has various applications, including use as a coolant in industrial processes, as a refrigerant in refrigeration systems, and as a propellant in rocket engines. It can also be used as a source of clean and renewable energy.

5. Are there any challenges associated with compressing air into a liquid state?

One of the main challenges is the high energy and equipment costs involved in the liquefaction process. There are also safety concerns due to the extreme pressures and temperatures involved. Additionally, there is a risk of air contaminants freezing and clogging the equipment, making it important to properly purify the air before compression.

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