How Does Raising Air Pressure in a Flask Affect Temperature and Maximum PSI?

AI Thread Summary
A biologist inquired about the effects of using a 100 psi air compressor on a one-liter glass flask filled with air, specifically regarding pressure and temperature changes. It was suggested that the pressure could increase by 100 psi, leading to a temperature rise proportional to this increase. However, a correction was made regarding the application of Boyle's law, clarifying that it only applies to a fixed mass of gas. The actual temperature of the gas would be influenced by the outlet temperature of the air compressor, which varies based on several factors. The discussion highlighted the complexities of gas behavior under compression and the importance of considering these variables.
Batata
Messages
1
Reaction score
0
Hi! I'm a biologist so be easy on me:)

Say I had a one liter glass flask filled with air and I had a 100 psi air compressor attached to it. (I don't want to suck air out but blow more inside!) How would the air in this flask react - according to the law of ideal gas the temperature of the air should start rising, but would I be able to increase the pressure in the flask as well? How much would I be able to raise the psi in the flask?

Thanks!
 
Physics news on Phys.org
i think if you had a 100PSI compressor, you could raise the pressure by 100PSI.
the volume would remain the same, so T would go up by the same factor.
100PSI is 14 times atmospheric pressure, so the temperature would increase by a factor of 14.

but I'm not 100% sure. hopefully someone else can either confirm I'm correct, or let you know what i did wrong.
 
dnp33
I'm sorry you are wrong, you seem to be applying Boyles law P1*V1/T1=P2*V2/T2 but this only works for a fixed mass of gas. The temperature of the gas in the flask in this instance would be about the same as the outlet temperature of the air compressor, which would depend on a huge number of factors.
 
ah i see.
thank you for the correction, i seem to have missed the fact that there was obviously air being pushed into the flask.
 

Thread 'Off resonance driving of a MW/RF cavity'

Hello! Let's say I have a cavity resonant at 10 GHz with a Q factor of 1000. Given the Lorentzian shape of the cavity, I can also drive the cavity at, say 100 MHz. Of course the response will be very very weak, but non-zero given that the Loretzian shape never really reaches zero. I am trying to understand how are the magnetic and electric field distributions of the field at 100 MHz relative to the ones at 10 GHz? In particular, if inside the cavity I have some structure, such as 2 plates...
View full post »

Similar threads

B How the temperature of the Earth's surface affects the air pressure above it
Replies
7
Views
2K
I Air quantity to blow up a tyre
Replies
8
Views
2K
How to predict the exit temperature of an air compressor?
Replies
33
Views
3K
I How weather conditions affect a golf shot
Replies
6
Views
3K
Water pressure affects air pressure
Replies
9
Views
3K
Flow rate of air through constriction
Replies
10
Views
3K
I Effects on Engine Overheating and Pressure Dynamics
Replies
4
Views
2K
How does air behave in the daisy chaining of compressors?
Replies
10
Views
4K
Why Did the Temperature Rise in a Sealed Automotive Cooling System?
Replies
18
Views
2K
Adiabatic Expansion of Pressurized Air in a Piston-Cylinder Setup
Replies
8
Views
2K

Hot Threads

Recent Insights

Back
Top