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Where did the 100 psi assumption come from?

Posted: Thu Nov 20, 2008 3:57 pm
by Radiation
On a standard combustion gun it is often tossed around that they are only capable of 100 psi at the most. While I have no evidence to the contrary I often scratch my head and think "where did this number come from?" I have done numerous searches that have turned up nothing of value. As a matter of fact from what I can tell there is no evidence what so ever that this number was ever anything factual at all.

A few things concern me with this number, was it attained by someone completely sealing a chamber, connecting a PSI gauge and igniting the mixture inside? If so how is it possible for something as inaccurate as a psi gauge to correctly capture a PSI spike that might last a millisecond or two? Psi gauges are notoriously bad at capturing spikes in psi. For that reason alone I would dispute this "100 psi" claim, however that is just the begininng of my dispute. :shock:

What size chamber is this 100 psi max theory based on? Would this necessarily matter? Perhaps not, but perhaps the natural properties of the chamber may vary based on volume, material, and yes even shape after all we are dealing with a millisecond event here. What is the ignition source? Are we talking about an even metered/chamber fanned mixture or just some right gaurd spray and pray?

It just seems to me that this number was randomly plucked from thin air (or somewhere else. :wink: ) If I'm wrong please point me to where this number is derived from and the data that was collected.

Thoughts? Anything I missed? Direct evidence? :oops:

Posted: Thu Nov 20, 2008 4:22 pm
by ALIHISGREAT
well you can't get above 100psi on HGDT for a non-hybrid combustion.

Posted: Thu Nov 20, 2008 4:30 pm
by jitup
what type of a meter would you use to find this, I am thinking that you would have to have an expensive electronic pressure sensor hooked up to a computer to monitor the whole event. Do these sensors even exist?
If I am way off I'm sorry but let me know so I can learn from my mistake :)

Posted: Thu Nov 20, 2008 4:41 pm
by jackssmirkingrevenge
Some hard data, courtesy of jimmy ;)

Posted: Thu Nov 20, 2008 4:48 pm
by Radiation
ALIHISGREAT wrote:well you can't get above 100psi on HGDT for a non-hybrid combustion.
And while it is a great tool the author of HGDT David Hall said it best when he wrote in his FAQ
What phenomena does GGDT (sic) not take into account?

Alas, no model is perfect and I am far from being a world renowned expert on internal gun ballistics. I wish I could claim laziness, but the simple fact is there are some topics for which I simply do not have the mental resources for. These topics were as a result, ignored....

Energy losses associated with turbulence or frictional forces between the gas and the gun's chamber/barrel walls. In other words, pressure drops due to bends or rough edges in the gun's plumbing

Realistic combustion modeling. I've done my best, but I know my attempts are crude.
what type of a meter would you use to find this, I am thinking that you would have to have an expensive electronic pressure sensor hooked up to a computer to monitor the whole event. Do these sensors even exist?
If I am way off I'm sorry but let me know so I can learn from my mistake


This is what logic would dictate. You would need an extraordinarily accurate and sensitive psi meter. The other route to getting a respectable understanding of such an event would be through mathmatical understanding of the reaction of propane and atmospheric air. I don't think that there would be an accurate representation for how all combustion based guns with either method, but at least that number would be based off of some sort of real world understanding and not this amorphous 100 psi assumption.

Posted: Thu Nov 20, 2008 5:06 pm
by Radiation
jackssmirkingrevenge wrote:Some hard data, courtesy of jimmy ;)
Wow Jimmy, great article! Very very well written. Excellent job on the data and researched.

I plucked a few lines from this to illustrate my point
In the vicinity of the peak piezo signal the signal is too complex to measure the frequency, the earliest frequency I could measure was at 32.8mS after ignition, about 8mS after the peak piezo signal.
this is the crux of the issue. Combustion is a very complex event and the ability to measure accurately when it counts most is elusive at best.
The gauge's response was recordable and the movie file is here. The image below shows 32 video frames recorded during the firing of the chamber. The camera's nominal frame rate is 30 FPS (one frame every 33.3mSec). In the first two frames the gauge's needle hasn't moved. In the third frame the needle is a blur in the range of 80 to 100 PSIG. In the next frame the needle is less blurry and the pressure has already dropped to about 76 PSIG. Over the next 24 frames (0.8 seconds) the needle is sharp in the images and drops down to 8 PSIG, which is the minimum reading of this gauge.


This 80 to 100 blur is concerning in that A. this is a very simple gauge that is designed to measure constant psi not accurately or sensitively capture a spike in pressure. B. In no way is video taping an gauge going to give you an accurate assessment of what's going on in the chamber.

This again illustrates my point, this is not as simple as looking at a gauge of a sealed chamber. There is a very complex reaction going on here.

Posted: Thu Nov 20, 2008 5:38 pm
by Fnord
You can look at it another way. For a given volume of air/propane at 95.98 : 4.02% (optimum mixture) you'll have a certain amount of energy available. This can be calculated.

If you find the specific heat of each combustion product and apply the energy from the reaction to them, you can find the net temperature increase from the reaction.

Figure out how much the gases expand at the new temperature and you'll get results that you can put into BAR/psi.

Or I think that's right at least :).

Posted: Thu Nov 20, 2008 6:05 pm
by Radiation
And that's exactly what I want to know.

Posted: Thu Nov 20, 2008 6:36 pm
by Velocity
Energy density of propane is approximately 2.45 MJ/M^3 (according to online source). I think this figure would be useful in calculations...not too inclined to do it myself right now.

Posted: Thu Nov 20, 2008 7:10 pm
by Fnord
Velocity:
By that number, an advanced combustion would only have about 250 joules total energy, figuring 6 cubic inches of propane for a 150 inch^3 chamber.

Posted: Thu Nov 20, 2008 8:14 pm
by Velocity
By conservation of energy, that would mean that a golfball would shoot out at about 340 ft/s, if all of the energy was imparted to it...does this number seem low? I don't know about the energy density number, it just came up in a search and had proper units.

Posted: Thu Nov 20, 2008 11:20 pm
by Ragnarok
That number is very low.

You're looking at the wrong figure. You want the energy change of combustion, which is 2,219,200 J/mol. (And yes, I know that off the top of my head, because I'm a total geek)

In real world terms, this means that per litre of propane/air mix at 0 degrees C (32 F), there are approximately 4000 Joules of energy released on combustion.

At 20 degrees C (68 F), this falls to 3700 Joules.

Interestingly, if you convert these energies into pressures, you get numbers like 550 psi.
I don't think I'm QUITE so tired that my maths has gone that bad (and if it has, I'm screwed, because the reason I'm still up is to do my maths assignment) - so I have to hope there's some factor I'm not seeing.

Posted: Fri Nov 21, 2008 2:46 am
by john bunsenburner
Some where we should have a huge pdf with ALL the formulas so that any moron like me can go and put the numbers into their calculator and tada have everything in black and white, or maybe some one could even make a program with ALL the formulas we will ever need...just a suggestion...

Posted: Fri Nov 21, 2008 2:07 pm
by jimmy101
The easiest way to look at the "max pressure" question is to just do the thermodynamic calculation for propane + air in a closed chamber.

GasEq will do it. Or, as others have posted, you can use the thermodynamic heat of combustion and calculate it yourself.

Bottom line is that in a closed chamber a perfectly measured and perfectly mixed mixture of propane + air, ignoring any possible heat loss (which means the estimate is a bit high) ... ~137 PSIA, ~122 PSIG.

Some might say "but that is a 'theoretical' result" and theory is often different than the real world. That is true, but in thermodynamics the real world always works less well than what the model predicts. In our case, it is unlikely that a real gun will reach the ~122 PSIG predicted value. Heat loss, less than perfect mixing or ratio, leakage etc all drop the actual peak pressure. There aren't really any mechanism that can increase the static pressure above what is predicted by theory.

(The only possible way to get an instantaneous pressure greater than predicted would be because of shock affects. If you get to DDT the peak pressure at certain points in the chamber can be much higher than thermo predicts. But, a shock wave last for a tiny length of time compared to the combustion process. The time domain is so short that the mass and momentum of the chamber will significantly increase the chambers ability to withstand that short duration pressure spike.)

So, worst case scenario would be a round jammed in the barrel. The chamber pressure would spike to about 120 PSIG. Within one second after ignition the gases would have cooled off enough so that the pressure in the closed chamber was back in the range of a few PSIG.

In a functioning gun the peak pressure is significantly less since the round will start to move before peak pressure is obtained. The moving round enlarges the chamber and the peak theoretical pressure drops accordingly. The combustion process is so slow that all rounds I've ever seen are moving well before the peak pressure is obtained. (A perfectly tuned burst disk gun might be able to get pretty close to the ~122 PSIG peak, but it won't ever actually reach the theoretical peak since there will always be some heat loss.)

So, the "100 PSIG peak pressure" actually should be more like 120 PSIG. That is a pretty firm number and is reliable. In a normally functioning spud gun the peak will be significantly less. In my experience, the peak pressure in typical spudguns is about 60 PSIG.

Posted: Fri Nov 21, 2008 2:34 pm
by Radiation
Hmm thanks for the info Jimmy. obviously burst disk and perhaps even a tighter fitting round will increase the likelihood that one may reach a release pressure potentially closer to the theoritical 120 PSIG, but because of the nature of most combustion guns you are looking at a more likely range of 60 or so PSIG.

Most of the time when the 100 psi number comes up is in regards to safety, but my question is more what the practical yield is and your post has answered that to my satisfaction! Thank you.