mag technical questions- amount of time air flows out of the bolt? and..

That should help you out.....some.

help me understand these test results a bit if you would.

from what I can tell, the bolt is actually letting air flow for about 3 to 3.5 msec? but it's actually only useful for 2.5 msec?

what about this information:
bolt .110 open-40
.060 open-60
barely open-77

is that a percentage of completion for how much the bolt is open or something?

any help understanding this would be greatly appreciated.

According to the legend, it's 10ms per 100 counts so......

I'm seeing the bolt fully open from somewhere around 3225 to 3250 = 25 counts = 2.5ms

3220 - 3260 (the full travel) = 40 counts = 4ms

The odd thing is breach pressure seems to start prior to bolt movement so there may be a little error in the test set up there.

3230 - 3260 = 30 counts = 3ms = the time the bolt is still open after the ball has started down the barrel.

It also seens that the bolt takes noticably longer to return than to extend,wonder how LX effects that.

Not sure about those 3 other figures. Not 100% sure about what I've just said.

Good luck.

I can offer some "eye ball" testing I have done. I know that I have got the valve cycling up to 34x a second. That would mean (would it not) that if the air is expelled in the 1st 1/2 of the bolt cycle it would be about 1/68th of a second (and probably less). Again that is not based off that graph, but my field tests.

well that is a helpful piece of info rrfireblade.

but it still leaves me wondering how far the piston comes out of the power tube. I know that the amount of time it is out of the power tube and the distance it travels out of the power tube are directly proportional, just like any other valve.

the graph shows the peak pressure behind the ball. it shows that air is coming out of the bolt, before it peaks, and as it descends, there is a small plateau. I'm curious as to what that is.

I'm guess I'm kind of beating around the bush here.
what I'm really interested in is the flow rate. how much air is flowing out of the bolt that is used to fire the paintball. not too concerned about the waste before hand. I know it has been stated that there is a residual pressure of 50 psi in the dump chamber after firing.

I want to calculate the air used during the shot by taking an operating pressure reading(gonna make something to do that) then subtract the stated residual pressure.

then use a flow rate calculation (given size orfice at a given pressure for a given amount of time type of thing) and see what the difference is. the difference should be waste, plus or minus a fudge factor of course.

it still confuses me why the mag needs as much operating pressure as it does to do the deed. with .55 cu. in. of chamber, it shouldn't take more than say, 250-300 psi to do the job with that kind of volume.

the new shockers have a dump chamber volume of .58 cu. in., and operate at 200 psi. they are only using 8.5 cu in of air to propel the ball. that is pretty good (that is with the evolve bolt kit though, not stock) the place where it suffers is the pressure going into the solenoid is the same going into the dump chamber. so the shocker use another 3.5 cu. in. of air to cycle the bolt.

all this research got me to thinking why the mag uses so much air and where it is losing efficiency.
the three variables in valve flow I think are : open time, open distance, and size of orfice.
the first to are related, and it is not really helpful to extend the open time and distance. I think it's orfice size. (I know shape plays a role, but I"m only really concerned in circular opeings) I think the 1/4 piston has limitations to it's flow capabilities.

I belive it is to overcome the force of the return spring?

That's exactly why, since you have the force from a heavily tensioned spring and moment of inertia from decently weighted bolt to overcome.

No.


put a weaker spring in your mag. don't change the reg at all. load it and go shoot over the chrono. guess what, it still needs the same pressure. that spring was designed specifically for the automag to return the bolt properly. I can see it being that simple with another gun, but not the automag. every single part of the automag serves two purposes. that doesn't happen by coincidence. it's specifically engineered.

besides, like I said more open time will not help no matter how it is acheived. the ball is gone in a few msec. any air expeled after that is wasted. a weaker spring let's the bolt move faster, open farther and stay open longer this wastes air. a weaker spring actually makes it less efficient.

my interest is this:

did the engineers who designed the gun try a larger bolt piston diameter? surely they ran some numbers or something. there has to be a reason they used the size they did.

I've been wondering if a higher flow rate could be acheived by a larger bolt piston, being more efficient and the pressure could be reduced.you could only go so big. with the existing power tube, probably no larger than a 5/16"(.312) bolt piston. a 3/8"(.375) would be better (like that of a matrix), but not possible with the existing power tube.

I've just notice that guns that really use the air efficiently, release the air in the same amount of time, but using an orfice with a larger flow rate. using less air.

now of course lower pressure air would have a lower velocity. I need to run some numbers to see for myself the feasibility of a large bolt piston. I would want the bolt speed to be about the same, so the pressure would have to be able to be lowered in proportion to the increase bolt piston surface area(force). the hardest part will be the orfice flow coefficient. I'll have to "reverse engineer" something.

Personally I don't think the piston O.D. is the problem,it's quite large compared to the air passages in most other guns. I think......'think' , the issue may have to do with the orrafice that's left when the piston/bolt is at the point where the majority of the air begins to dump from the chamber.It's not possible for the piston to be completely out of the power tube for obvious reasons,so..... as soon as it get's near the mouth of the PT tip,the internal pressure will flow ASAP and almost as quickly,the bolt will lose it's fight with the spring and start back home.That apparenty small gap/space/whatever that exists for a ms or so is possibly the 'restriction' in the flow the may be having a negative effect on efficiency.The biggest problem, IMO, with the cork in the bottle design is that the 'dumping' of the chamber is not as instantanious as a typical sheridan style and the flow must pass through an orafice that 'leaks' initially and never reaches a linear sized apature until after the majority of the pressure has already done it's job,by then it's too late.

Not to mention that the bolt is still flowing air well after the ball has left and 'dumps' almost all excess air/presure (within ~50psi or so) that could be left as part of the next 'charge'. That's one of the primary reasons Matrices and SFT Shockers were so bad on air and how the new bolts for them increased thier efficiency.

Or not............

Ouch, given a smack down before, time to try again..

I think you're right in that increasing orfice size should increase efficiency. But the question is pertaining to other markers. I wonder how the graph would look like for other guns, and what the curve of the pressure behind the ball looks like. perhaps their release is much more abrupt, instead of the somewhat gradual release that a lvl 7 powertube tip results in.

Maybe machining a tip that is not sloped, but rather a square edge would show some change in the way air is handled, and more is released when the ball is still in the barrel, and used to propel the ball instead of going to waste. At that point, we could drop the pressure to compensate for the higher fps. So with a same release time, and a lower pressure (which is less air for the same amount of space) we would get better efficiency numbers?

Also is where the square edge is in relation to the end of the powertube tip may be important, since a too early release results in a ball tha isnt fully chambered, and a bolt that isn't sealed totally in the breech.

I'm probably totally off on this..

Edit: Just reread, and this is basically pertains to the issue that RRfireblade mentioned

thanks for the reply rrfireblade.

as far as orfice size, it's only a 1/4" . that's about the same as a cocker body, but smaller than other, such as matrix, new shockers, and other low pressure guns.

I see what you're saying about the early release, but not about the bolt piston. it is not flush with the back of the bolt, it is inset about .210" on a standard bolt. I think it is possible for it to come out of the power tube to let the air by. the inner bolt surface rides on the outside of the power tube and the bolt is guided fairly well, when combined with the body keeping the bolt centered. but my thought has always been that as soon as it comes out (if it does) it loses so much pressure, that the spring keeps it from being open very far at all, and for very long. that's what made me think about increasing the diameter of the bolt piston to increase the release of air at that point. but I can see that it would probably increase the amount that was prematurely released also.

I definitely agree with you about the lack of instantaneous air release. poppet valves work much better for this.

so I guess it's back to how to keep the bolt from leaking during the bolts forward and aft movement.


I have seriously thought about making my own spool valve design to fit in an automag. something more efficient than the mag,shocker, or matrix.

Yes, that's pretty much what I have in mind as well,I think we're both on the same page. I'm just thinking that it never fully clears the opening of the PT. Keep in mind I haven't measured a thing, just thinking off the top of my head here.

The idea I had some time ago was to use a pump mag type set up but using a ram to control the bolt movement and no bolt spring at all. A minor redesign of the bolt piston and power tube tip for instantanious (pretty much) pressure release in .75" or less of s stroke and the whole shibang being 'timed' exteranlly thru the ram and associated hardware/electronics.

Just a thought.......

* oh yeah.....1/4" is a huge opening,far more than what you see get passed the average poppet valve,cup seal style gun. (cocker etc) even with a relieved cup seal shaft. *

I understand what you've posted RR, but what you're describing is an accurate description only in terms of the currently produced bolt/piston assembly. Following E's reasoning, in the very least, if the piston were a larger outer diameter, wouldn't a larger volume of air be able to escape in the same amount of time since the gap between the bolt piston and oring/power tube tip is larger, in turn reducing the amount of wasted bleed between the point where the bolt fully opens and closes again? In other words, as the outer diameter grows, couldn't more air be instantaneously released, rather than gradually bled off and wasted?

I'm wondering if the current design isn't so much a matter of engineering, but rather a result of the limitation in materials that were available in the late 80s, the safety features built into every stage of the valve assembly, and the fact that it is rated to 3000 PSI.