I’ve recently added to my monthly 200 yard silhouette
match. I’ve gone out to a mid and long
range match starting at 300 and going out to 1000 yards. Now I’ll admit, I don’t use the 38-55
Trapdoor beyond 600 yards, but it does get to reach out a bit. Besides the eye opening challenge of shooting
long range in a 25MPH side wind, I discovered an additional issue. My .38 bullets seem to be going unstable at
the longer range. I knew they were OK at
300 yards because I can do a lot of testing at that range locally, but 600
yards is harder for me to get time at.
A book was suggested to me.
“Understanding Firearm Ballistics” by Robert Rinker. It was pretty straight forward and came with
one formula on basic stability that would help me compare my current “OK”
bullet with any new bullet I want to try.
The formula basically compares the moment of inertia of the bullet in
the spin direction with the moment of inertia in the tumble direction. It also has a term for the RPM of the bullet
spin, which turns out to be a fairly heavy player.
So labeling:
N=RPM
A=MOMENT OF INERTIA IN SPIN
B=MOMENT OF INERTIA IN TUMBLE (OR YAW-it should be the same
either way).
S=”STABILITY”. I will
be treating it as a dimensionless number as long as all my input numbers use
the same units from one bullet to the next.
U= A shape factor. I
have no way of calculating this, so I choose to ignore it. Easy, eh?
The basic formula is:
S=A^2*N^2/(B*U)
I apologize for my poor math text layout.
The important thing to notice is that stability goes up as
the square of the moment of inertia in spin and the square of velocity. So a short squat fast bullet should be highly
stable.
The next step is to compare my current bullet with my new
bullet. A little time with a cad program
and some calipers and I had my numbers.
The pictures below show my two bullets.
My current bullet is a Postell style that weighs 336
grains. It is a Lyman 378674DV
The Round Nose Flat Point weighs 305 grains. It is a Redding Saeco 65571 #571.
The Postell has a CG that is 6.3% of the length back of the
center. The RNFP CG is 4.1% back of the
center. This in itself will add some
stability as the tendency of the nose to lift is reduced.
The Postell “A” value is .0007675 LB*in*in compared to
.0007279 for the RNFP.
The Postell “B” value is .005918 as compared to .004374 for
the RNFP.
So, assuming the muzzle velocity is unchanged (which, sadly,
seems to be the truth despite the lower weight) I get an increase of stability
of right at 20%. Which is sizeable, but
is it enough?
Well, off to the range.
At 300 yards, the new, shorter, bullet throws a 10 shot group with a
standard deviation of 1.56. The older,
postell, bullet throws a standard deviation of 3.76. This is a big chunk and the smaller bullet
has become my baseline. However, at 300
yards, it doesn’t really answer my question.
Is it more stable at 600 yards?
Unfortunately, the data acquisition at 600 is a little tougher. In matches, each shot is marked by a target
puller and can be viewed from a scope, but that’s a lot less accurate than
measuring paper. So my answer right now
is “I don’t know.” Hopefully, sometime
in the spring, I can get to a test range during low wind and shoot some test
targets.
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