i posted this was on the other site in OSR and i remembered i wanted to bring this over here.
just a reminder, for those shooting suppressed 22lr and looking to cut out the sonic crack, the speed of sound varies with temperature. this is the only thing that causes a variation in the speed of sound, and atmospheric pressure has no bearing on it.
i had to remind myself about this as i was shooting at the ranch on Saturday and it was roughly 37 degrees outside, and i was getting sonic crack with bulk pack through my 4.5" barrel AR with a can. so what was happening was the speed of sound in the colder air is much slower, and therefore a bullet velocity of a 22lr advertised at 1260 FPS on the box, out of a 4.5" barrel was still breaking the sound barrier.
for those wondering, here are a few equations and a refresher on calculating speed of sound.
we'll use U.S. Customary Units.
k= specific heat of air = 1.4
gc= gravity = 32.2 ft-lbm/(lbf-sec^2)
R= specific gas constant for air
T= absolute temperature in Rankine= degrees in F plus 460 (or 459.67 to be exact)
1st, calculate the specific gas constant:
R= R* / MW
R* = universal gas constant in Rankine units = 1545.4 ft-lbf/lbmol-Rankine
MW = molecular weight of air = 28.967 lbm/lbmol
R= 1545.4 / 28.967 = 53.35 ft-lbf/lbm-Rankine
Temperature at my shooting time: 37 deg F = 497 Rankine
Therefore:
Ss = sgrt[ (1.4)(32.2)(53.35)(497)]
Speed of sound on Saturday was = 1093.3 FPS
so to simplify this down, to calculate speed of sound for a given temperature (x in Fahrenheit), use this equation:
Ss = sgrt[ (1.4)(32.2)(53.35) (x+460)]
obviously, these equations treat air as an ideal gas.
applying this to my situation leads to the conclusion that the 4.5" barrel was not able to slow a 22lr bullet down from an advertised 1260 FPS to below 1093 FPS.
just food for thought.
just a reminder, for those shooting suppressed 22lr and looking to cut out the sonic crack, the speed of sound varies with temperature. this is the only thing that causes a variation in the speed of sound, and atmospheric pressure has no bearing on it.
i had to remind myself about this as i was shooting at the ranch on Saturday and it was roughly 37 degrees outside, and i was getting sonic crack with bulk pack through my 4.5" barrel AR with a can. so what was happening was the speed of sound in the colder air is much slower, and therefore a bullet velocity of a 22lr advertised at 1260 FPS on the box, out of a 4.5" barrel was still breaking the sound barrier.
for those wondering, here are a few equations and a refresher on calculating speed of sound.
we'll use U.S. Customary Units.
Ss= speed of sound
k= specific heat of air = 1.4
gc= gravity = 32.2 ft-lbm/(lbf-sec^2)
R= specific gas constant for air
T= absolute temperature in Rankine= degrees in F plus 460 (or 459.67 to be exact)
1st, calculate the specific gas constant:
R= R* / MW
R* = universal gas constant in Rankine units = 1545.4 ft-lbf/lbmol-Rankine
MW = molecular weight of air = 28.967 lbm/lbmol
R= 1545.4 / 28.967 = 53.35 ft-lbf/lbm-Rankine
Temperature at my shooting time: 37 deg F = 497 Rankine
Therefore:
Ss = sgrt[ (1.4)(32.2)(53.35)(497)]
Speed of sound on Saturday was = 1093.3 FPS
so to simplify this down, to calculate speed of sound for a given temperature (x in Fahrenheit), use this equation:
Ss = sgrt[ (1.4)(32.2)(53.35) (x+460)]
obviously, these equations treat air as an ideal gas.
applying this to my situation leads to the conclusion that the 4.5" barrel was not able to slow a 22lr bullet down from an advertised 1260 FPS to below 1093 FPS.
just food for thought.
