Lloyd, that is very interesting. Thanks for this "real-world" analysis!
A question about the picture; was the issue thread strength per se, or was it that the tube was thin enough at the root of the threads that it was actually stretching there? Either way a failure, of course!
Hi Andy,
You are correct, the threads themselves were fine, but the wall thickness at the thread root was thin. The tube O.D. was .875, and the max major dia of the internal thread was a nominal .8125, so the wall thickness could have been as thin as .031. The tube material has a yield of 72ksi and a tensile of 87ksi. You can see that the o-rings for the tube plug are in-board of the threads, so the threaded section sees basically no hoop stress. The axial load on that plug, when yield starts is 5,100 pounds force, and max tensile force was with 6,200 pounds force. At the rated max fill pressure of 3000psi, the force on the end plug is only 1,300 pounds force, so, plenty of safety factor. But pressurized to 15,000psi when the burst failure occurred, the axial force on the plug was 6,500 pounds force, so, the end of the tube could have popped off instead of the tube wall ripping open.
But here is the good news about the test, which gave many airgun owners peace of mind when I posted the video of this years ago. Currently, the max fill pressure that can be achieved with readily available small air compressors is 4,500 psi. So even if someone was careless and over-filled their 3,000 psi tank to 4,500psi, failure of the tube and end plug would not occur. But also, a proper design for such a tube is to design into the tube a source of benign failure that happens before a catastrophic failure occurs. In such air tubes, designing the failure into the o-rings is the usual method of choice. With excess wall clearance between the plug O.D. (where the o-ring is) and the tube wall, the o-ring will extrude thru the gap with a loud pop and all the air will be gone in an instant. Scary, but it will put the fear and respect back into you, LOL!!!
This test was done with hydraulic oil because doing it with air would have basically created a bomb because of all the potential energy in the compressed air. Hydraulic oil leaks past o-rings differently than air, and I think I just used 90 duro o-rings instead of 70 duro o-rings to make them more resistant to the high pressure of the test.
My apologies if I am hijacking the thread, but I hope these safety tid-bits raise a few eyebrows and make us think about what we are doing in our shops every day.
Just a little more, but very important. The other end of the tube is sealed by a valve cartridge with o-rings that is secured with three 10-32 cross screws. But CO2 versions (nominal 800psi) have only a pair of 6-32 screws. A guy who didn't really understand what he was doing managed, with great effort, to put high pressure air into his CO2 gun and blew the valve (a chunk of .75dia x 2" long aluminum) out the end of the tube and into his thigh. Luckily he survived ok. There is a graphic youtube video of this. Another big safety reminder. !
Again, my apologies for the long post. I lost a little finger to a table saw at age 15, but I still have the other 9. And
it happened because I did something that I had no idea was wrong and dangerous.
Lloyd
