Time till the air pressure is gone

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Discussion Overview

The discussion revolves around estimating the time it would take for an 8 gram cartridge of N2O to empty when punctured with a 1 mm hole. Participants explore the physics of gas dynamics, pressure differences, and the implications of phase changes in the gas during the outflow process.

Discussion Character

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

Main Points Raised

  • One participant seeks to calculate the time for the N2O cartridge to empty after puncturing it, providing initial parameters such as pressure and volume.
  • Another participant provides an order of magnitude estimate, discussing the acceleration of gas and initial escape velocity, suggesting that the timescale for emptying would be fractions of a second initially.
  • A participant questions the density calculations, noting a discrepancy between the provided density and that predicted by the ideal gas law, suggesting that the gas may not behave ideally due to pressure conditions.
  • There is a discussion about whether the 8 grams refers to the gas alone or includes the cylinder, with clarification that the cylinder's weight is significantly more.
  • Some participants suggest that the container may contain both gas and liquid N2O, which could affect the time it takes to empty the cartridge.
  • Concerns are raised about the complexity of solving the problem analytically if phase transitions are considered during the outflow process.
  • One participant expresses a preference for a simpler approximation, assuming constant phase conditions for the sake of estimation.
  • Another participant reiterates the importance of understanding the phase behavior of N2O under pressure, noting that the ideal gas law may not apply due to the liquid state at certain pressures.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the assumptions regarding the phase of N2O during the outflow, and there are competing views on the implications of density calculations and ideal gas behavior. The discussion remains unresolved regarding the exact time it would take for the cartridge to empty.

Contextual Notes

Limitations include the dependence on assumptions about the phase of N2O, the accuracy of density calculations, and the potential for varying behavior under different pressure and temperature conditions.

zach_wildmind
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Hello, I have a 8 gram cartridge of N2O meant for kitchens. Long story short from what I understand it has 10 cm cube of N2O inside. I also know it has 900 psi / 60 bar of pressure inside. The cylinder is exactly like this image.
Food-Grade-Nitrous-Oxide-Cream-Chargers-8g-N2o.jpg


I am trying to find out how much time it would take if I puncture a hole of 1 mm (millimeter) in the bottom to be completely empty. Basically I am trying to find a way to calculate the time needed for the cyclinder to be empty. Any help is appreciated.

Thank you!
 

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  • Food-Grade-Nitrous-Oxide-Cream-Chargers-8g-N2o.jpg
    Food-Grade-Nitrous-Oxide-Cream-Chargers-8g-N2o.jpg
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Order of magnitude estimate: A 60 bar = 6 MJ/m3 pressure difference can accelerate something with 100 kg/m^(3) (your gas inside) with 60 kJ/kg, enough to make it reach close to the speed of sound where this approximation becomes bad. Anyway, at that speed you have an initial loss of 350 m/s * 1mm2 = 350,000 mm3/s = 350 cm3/s. As some gas escapes pressure and temperature inside drop, slowing the escape, but the timescale is still fractions of a second. After a second or two your interior pressure will be nearly identical to the exterior pressure. You still have N2O inside, probably quite cold now. As it warms up to room temperature again a bit more of it will escape. Over much longer timescales random air motion and diffusion will let air in and the remaining N2O out.
 
wow, that helped a lot. Given the speeds I can now approximate the time. Thank you
 
This can be solved analytically with some relatively simple and well-justified assumptions.

I'll also note that your numbers don't seem to add up. If you have 8 g of N2O occupying 10 cm3, then that implies its density is 800 kg/m3. At the same time, if you take the initial pressure you gave and assume room temperature, then the ideal gas law would imply that the density is only 115 kg/m3.
 
Last edited:
boneh3ad said:
If you have 8 g of N2O
Is that 8g of gas, or 8g of cylinder?
No. it must be gas only. The cylinder will weigh considerably more than 8g.
 
A bit of googling suggests these containers have 8 grams of N2O with a total mass of about 30 grams.

The density of liquid N2O is 1.3 g/cm3 by the way. It becomes liquid at room temperature at ~50 bar, so maybe it has a combination of gas and liquid? Then it could take longer to empty these containers.
 
I attended some lectures last year on safety/industrial accidents and this kind of even (possible outflow from a container) was studied carefully although, for the sake of simplicity, the phase was assumed to remain constant.

If you have to take into account the phase transition during the outflow, this might be a little pain to solve analytically. I would like to know how you take this scenario into account.
 
dRic2 said:
I attended some lectures last year on safety/industrial accidents and this kind of even (possible outflow from a container) was studied carefully although, for the sake of simplicity, the phase was assumed to remain constant.

If you have to take into account the phase transition during the outflow, this might be a little pain to solve analytically. I would like to know how you take this scenario into account.
I will simply assume that remains constant as all I need is an approximation of time. Thank you very much!
 
boneh3ad said:
This can be solved analytically with some relatively simple and well-justified assumptions.

I'll also note that your numbers don't seem to add up. If you have 8 g of N2O occupying 10 cm3, then that implies its density is 800 kg/m3. At the same time, if you take the initial pressure you gave and assume room temperature, then the ideal gas law would imply that the density is only 115 kg/m3.

The seeming discrepancy here is solved because pressurized containers of N2O are a liquid below 97F (if above about 700-1000 psi, depending on temperature - the critical point is about 1000psi at 97F), so the ideal gas law does not apply.
 

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