The next county should be safe. Anecdotally, I have seen a few tons of 2" thick head (about 8ft dia) break loose, tearing off 12" pipe connections, go 100' up and land 300' away; due to 300 psi nitrogen. You add explosions or detonations and it seems pretty difficult to predict a "safe" zone.
I found ASME PCC-2-2008 Repair of Pressure Equipment & Piping. In the mandatory appendix is a method for calculating stored energy & safe distance (pg. 197-198). This was sufficient for what I was doing, but I have heard there is a NASA document that addresses this issue, if any one has that reference, please share. Thanks for the comments
I wrote something that I think is pretty much exactly what you are looking for. It is based on the NASA-Glenn approach, which used to be in the public domain via their website, but is tough to find now. I even wrote a little spreadsheet that calculates the stored energy levels and safe working distances for you. If you want, I will make it generic and upload it.
E = Energy in Joules
P = Absolute pressure in Pascals
V = Test volume in M3
Patm = Atmospheric pressure in Pascals
k = Ratio of specific heat of air
Then convert to TNT:
TNTlb = E x 4.8 x 10-7
The safe distance can then be calculated by: SD = 15 (TNTlb).5
I use this for calculating safe working distance for all pnuematic tests. There are similar for hydrotests, but the stored energy is obviously a whole lot less.
Greg Lamberson, BS, MBA
Consultant - Upstream Energy
Website:
If I take the liberty of pirating Greg Lamberson's posted equations, I obtain the revisions per the attached link. The agreement in results is pretty good based on the cases I ran. The differences are probably because the curve fit correlation that I used for the NASA-Glenn curve probably could be improved a bit.
Greg Lamberson's equations may be better than mine.
