UCRL-ID-130055 Rev 1
A Library of Prompt Detonation Reaction Zone Data
P. Clark Souers
June 1998
This ie an informal report intended primarily far internal or limited external distribution Theopinionsandconclusionsstatedare thoseoftheautharandmay or may not be those of the Laboratory
Work performed under the auspices of the US Department of Energy by the Lavrence Livermare National Laboratory under Contract W-7405-Eng-48
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Abstract Tables are given listing literature data that allows calculation of sonic reaction zones at or near steady- state for promptly-detonating explosive cylinders The data COWIS homogeneous, heterogeneous, composite, inorganic and binary explosives and allows comparison across the entire explosive field Table I lists detonation front curvatures Table 2 lists Size Effect data, ie the change of detonation velocity with cylinder radius Table 3 lists failure radii and detonation velocities Table 4 lists explosive compositions A total of 51 references dating back into the 1950’s are given Calculated reaction zones, radii of cuvahue and growth rate coefficients are listed
Table of Contents
I Description ofthe Tables
Table 1 Detonation Front Curvature Table 2 Size Effect Table 3 Failure Radius Table 4 Compositions of Explosives Table References
I-3 I-4 I-4 I-5 I-5
II Comparing the Data
Tables
II-1
Table 1 Detonation Front Curvature T-l Table 2A Size Effect Homogeneous and Heterogeneous T-5 Table 2B Size Effect Composite and Inorganic T-12 Table 3 Failure Radius T-18 Table 4 Compositions of Explosives T-2 1
I-2
I. Description of the Tables
The intent is to collect steady state, prompt
detonation data that pertains to calcuation of the
average sonic reaction zone length, ie the
distance behind the detonation front that
furnishes chemical energy to push the front WC
hae present results on the detonation front
curvature in cylinders and the Size Effect, ie the
change of detonation velocity with cylinder
radius The data is listed plus the calculated
parameters that constitute the input to Larry
Fried’s upcoming LLNL code KINETIC
CHEETAH
Table 1: Detonation Front Curvature
A collection of cylinder detonation front
curvature data , as obtained from streak camera
measurements, follows, necessarily compressed
from the original data files The data is divided
into sections with attempts to create. families
The 92 5-97 5 wt% TATB family is the only
one where explosives from different sources are
collected, because of the general agreement
between samples The ANFO and PBXW-111
families are separated not only as to where they
came from but also whether they are confined or
unconfined In each family, the data is ordered
from small to large radii
The sections may be seen to fall into larger
groups Most of the table is made up of
“quadratic” curvahxes, ie those where the
radius-squared makes up half or more of the lag
and where the curves are smooth across the
I-3
entire diameter The top sections are
homogeneous and heterogenerous explosives, the
bottom sections are composites Near the bottom
comes the small set of “non-quadratic” curves,
which have steep edge lags and ragged centers
These occur only for explosives with short
reaction zones We next have the extreme non-
quadratic curves where defects of the order of
100th the cylinder radius have severely broken
up the front but steep edge effects are still clearly
visible Finally, we have three quadratic slabs
with a square cross section
The columns contain the following
1) the explosive name
2) initial density, p0
3) initial outer radius of the explosive, %,
and inner radius of a metal sleeve if present, for a
cylinder For the slabs, R, is the half-width
4) measured edge lag, L,, where the data was
taken all the way out to the edge
5) calculated reaction zone lengths, <.x.> in
mm using the theory from P C Souers and R
Garza, “Kinetic Information from Detonation
Front Curvature, ” Eleventh Internatiorzal
Defonofion Symposium, submitted
6) measured detonation velocity, U,, for the
radius R,
7) infinite-radius/infinite containment
detonation velocity, D, obtained by the
extrapolation of the inverse radius to zero
8) lag-fit coefficient of the radius-squared,
A, which describes the sideways energy flow
across the entire cylinder
9) lag-fit coeffuzient of the radius to the sixth
power, B, which describes the effects of the
edge Note A quadratic cuve is fit by the lag
equation L = AR* + BR6, a non-quadratic
curve is fit by BR6
10) measured edge angle, where the error is
generally +5O to ilO0
11) calculated edge angle, obtained from the
derivitive ofthe lag tit equation
12) growth rate coefficient, G, in the
GP*(l-F) overall explosive reaction rate
13) radius of curvature on the cylinder axis,
h”, as obtained directly from the curvature fit
coefficient A
14) wall confinement material, if any
15) wall confinement thickness in mm
16) energy conductivity, K (in MWlmn?),
as calculated from the quadratic coefficient, A,
and which seeks to describe transverse energy
flow across the cylinder
17) length of cylinder in mm
18) reference
The material of confinement is listed where
known, even though its effect might have been
negligible The abbreviations are
Br brass, 8 56 gicc
Cb cardboard, 0 5 g/cc
Cu copper, 8 93 g/cc
PVC plastic, 1 5 g/cc
Py pyrex glass, 2 2 g/cc
SS stainless steel, 7 8 g/cc
I-4
Some explosive families have been studied
in different places The abbreviations for these
ax
1) PBXN-111 N = U S Navy, A =
Australia
1) ANFO NM = New Mexico, SW =
%veder
Table 2. Size Effect
The Size Effect is the change of detonation
velocity with cylinder radius The data listed is
1) name, density, pre-pressed explosive
particle size and reference
2) radius, R,, in mm
3) measured detonation velocity in mm&s
The first entry opposite R, = m is the
extrapolated infinite radius detonation velocity
4) calculated reaction zone length, ix*> in
mm
5) the first number is the C-J pressure as
calculated by CHEETAH It is used to calculate
the growth rate coefficient, G, listed below it
6) radius of curvature, R,,,, on the cylinder
axis as calculated from the detonation velocities
Table 3. Failure Radius
The failure radii of page 1 are mostly the
subset of the Size Effect Listed are the
following
1) density in g/cc
2) failure radius, Rf (mm) We use only
data sets where it mentions that failure was
observed The failure radius is the average of the
smallest radius for which detonation was
observed and the largest at which it was not
The definition of failure is set by the researcher
Campbell required propagation beyond four 50
mm-long rate sticks for PBX-9502,26 which is
undoubtedly far stricter than the average
definition All samples are unconfined unless
noted
3) approximate detonation velocity at
failure, U,f (mm@) This is usually the last
measured value lowered to the nearest 0 1
mm&
4) infinite-radius/infinite containment
detonation velocity, D, obtained by inverse-
square extrapolation of the radius to zero
5) extrapolated sonic reaction zone length at
failure, ix& (mm)
6) calculated growth coefficient G
7) calculated radius of curvahue on the
axis, %,, (mm)
8) reference
Page 2 has the void volume fraction, fv, and the
inert material fraction ff and their sum
Table 4. Compositions of Explosives
All compositions are in wt %
ACKNOWLEDGEMENTS
We wish to thank Jerry Forbes, Per-Anders
Person, John Bdzil, Damian Swift, Finn
Ouchterlony and David Kennedy for their kind
assistance in supplying curvature data from their
laboratories This work was performed under
the auspices of the U S Department of Energy
by the Lawrence Livermore National Laboratory
under contract number W-7405-ENG-48
References
1
2
3
4
5
6
7
8
9
10
LLNL Cylinder Test
John Bdzil, Los Alamos National Laboratory, Los Alamos, NM, private communication, 1996
J B Bdzil, J Fluid Mech 108, 195-226 (1981)
R Engleke and J B Bdzil, Phys Fluids 26, 1210 (1983)
Alan Collyer and Damian Swift, AWE, Aldermaston, Great Britain, private communication, 1996
H Moulard, J W Kury and A Delclos, “The Effect of RDX Particle Size on the Shock Sensitivity of Cast PBX Formulations,” Proceedings Eighth Symposium (International) on Detonation, Albuquerque, NM, July 1519, 198S, pp 902-913
H Moulard, “‘Particular Aspect of the Explosive Particle Size Effect on Shock Sensitivity of Cast PBX Formulations,” Proceedings Nintk Symposium (International) on Detonation, Portland, OR, August 28- September I, 1989, pp 18. 24
J W Forbes, E R. Lemar, G T Sutherland and R N Baker, Detonatim Wave Curvature, Corner Turning and G’nreacted Hugoniot of PBX’GI I I, Naval Surface Warfare Center Report NSWCDDITR-921164, Silver Spring, MD, 1992 PBXN-11 I was previously called PBXW-115
David Kennedy, ICI Australia Operations, Kurri Kurri, New South Wales, Australia, private communications, 1995, 1997
U Nyberg, J Deng and L Chen, M&zing av Detonationshastighet och Krokningsfront i Samband med Brinnmodellu~ecklillgfor Emulsionssprangamne KI, Swedish Rock
I-5
Engineering Research, Stockholm, SveBeFo Report 6, 1995
11 J Deng, S Nie and L Chen, Determination of Burning Rate Parameters for nn Emulsion Explosive, Swedish Rock Engineering Research, Stockholm, SveBeFo Report 17, 1995 Finn Ouchterlony kindly sent the Swedish Rock reports
12 Jaimin Lee, Detonation Shock D.wamics of Composite Ewrgetic Mafer ials, PhD Thesis, New Mexico Institute of Mining and Technology, Socorro, New Mexico, 1990 Per-Anders Persson kindly lent us a copy of the thesis
13 F Chaisse’ and J N Oeconomos, “The Shape Analysis of a Steady Detonation Front in Right Circular Cylinders of High Density Explosive Some Theoretical and Numerical Aspects,” Proceedings Tenth Symposium (International) on Detonation, Boston, MA, July 12-16, 1993, pp 50-57
14 E R Lamar and J W Forbes, “Detonation Wave Curvature of Cast Comp B and PBXN- 111,” American Physical Society Topical Group on Shock Compression, Colorado Springs, CO, June 28.July 2. 1993, Proceedings, pp 13X5-1388
15 J W Forbes and E R Lamar, “Detonation Wave Velocity and Curvature of Brass Encased PBXN-11 1,“American Physical Society Topical Group on Shock Compression, Seattle, KA, August 13-18, 1995, Proceedings, pp 787-790
16 E R Lemar, J W Forbes and G T Sutherland, “Detonation Wave Velocity and Curvature of IRX-4 and PBXN- I IO,” American Physical Society Topical Group on Shock Compression, Seattle, WA, August 13-18, 1995, Proceedings, pp 791-794
17 G T Sutherland, E R Lamar, J W Forbes, E Anderson, P Miller, K D Ashwell, R N Baker, and T P Liddiard, “Shock Wave and Detonation Wave Response of Selected HMX Based Research Explosives with HTPB Binder Systems,” Anwican Physical Society Topical Group on Shock Compression. Colorado Springs, CO, June 28-J+ 2, 1993, Proceedings, pp 1413.1416
T-h
18 W H Wilson, J W Forbes, P K Gustavson, E R Lemar and G T Sutherland, “Detonation Properties of the Non-Ideal Explosive PBXW-123,” American Physical Society Topical Group on Shock Conzpressiolt, Seattle, WA, August 13-18, 1995, Proceedings, pp 795-798
19 J 0 E&man and D Price, Comparisorl of Curvature o/Detonation Front in AP with thatfound in some Conventional Explosives. U S Naval Ordnance Laboratory, White Oak, MD, report NOLTR 69-235 (1970) The listed lag axis has been multiplied by 100
20 M J Urizar, E James, Jr and L C Smith, “The Detonation Velocity of Pressed TNT,” Third Symposium on Detonation. Princeton. NJ; ~Se&mber 26-28, 1960, bp 327-356
21 E A Igel and L B Seely, Jr, “The Detonation Behavior of Liquid TNT,” Second ONR Symposium on Detonation, White Oak, MD, Februmy II, 1955, pp 439-453
22 LASL Explosive Propeity Data, T R Gibbs and A Popolato, ed (University of California Press, Berkeley, 1980), section following p 236 The XTX-8003 “diameters” on p 249 are really radii (see ref 27)
23 M E Malin, A W Campbell and G W Mautz, “Particle Size Effects in One- and Two-Component Explosives,” Second ONR Symposium on Detonntiou, White Oak, MD, February II. 1955, pp 478.493
24 L B Chapman, “NT0 Development at Los Alamos,” Proceedings Ninth Symposium (International) on Detormtior~, Portland, OR, Augurt 28-Septmeber I, 1989, pp 1001-1006
25 P Gimenez, P Chabin, J Mala and C Spyckerelle, “An Extensive Experimental Study of Pressed NTO,” Proceedings Tenth Zntetnational Detonatiorl Symposium, Boston, MA, July 12-16, 1993, pp 276.283
26 A W Campbell, “Diameter Effect and Failure Diameter of a TATB-Based Explosive,” Propellants, Explosives, Pyrotechnics, 9, 183-187 (1984)
27
28
29
30
31
32
33
34
35
A W Campbell and R Engelke, “The Diameter Effect in High-Density Heterogeneous Explosives,” Proceedings S&h Symposium (Intetnational) on Detonation. Coronado, CA, August 24-27, 1976, pp 642- 652
R H Dinegar, “Detonation Velocity of PETN in Small Confined Cylindrical Charges,” Propellants, Explosives, Pyrotechnics, 1,97-100 (1976)
C D Hutchinson, G C W Foan, H R Lawn and A G Jones, “Initiation and Detonation Properties of the Insensitive High Explosive TATB/Kel-F 800 95/5”, Proceedings Ninth Symposium (International) on Detonation. Portland, OR, August 28-Septmeber 1, 1989, pp 123. 132
M A Cook, E B Mayfield and W S Partridge, “Reaction Rates of Ammonium Nitrate in Detonation,” J Phys Chem 59, 675-680 (1955)
P C Sows, D B Larson and C M Tarter, Performance Calculations on fhe ANFO Explosive Ry-HD, LLNL report UCRJ-ID-118969(1995) TheRX-HDwas from Dyno Nobel
F Helm, M Finger, B Hayes, E Lee, H Cheung and J Walton, High Explosive Characterization for the Dice Throw Event, LLNL report UCRL-52042 (1976)
Hino and Yakogawa, data scanned from W E Gordon, “Detonation Limits in Condensed High Explosives,” Proceedings Four tk Symposium (International) on Detonation, white Oak, MD, October 12. 15, 1965, pp 179-197, see Fig lc
R H Hales, Final Repot t for the QM-IOOR Program, IRECO Inc , West Jordan UT, submitted to New Mexico Engineering Institute, Albuquerque, NM, March 19, 1993
QM-100 obtained with some data from Clark Banner of IRECO Inc , West Jordan UT, 1993 Also supporting data from R Simpson, LLNL, in conjunction with the QM-100 cylinder shots at LLNL, 1992
36
31
38
39
40
41
42
43
I-7
M A Cook and W S Partridge, “Detonation Properties and Reaction Kinetics of 2,4-Dinitrotoluene,” J Pkys Ckem, 59, 673-675 (1955)
L N Stesik and L N Akimova, “An Indirect Method of Estimating the Reaction
Zone Width of a Detonation Wave,” Russ J Pkys Ckem. 33, 14% 151 (1959)
M A Cook, R T Keyes, W S Partridge and W 0 Ursenback, “Velocity-Diameter Curves, Velocity Transients and Reaction Rates in PETN, RDX, EDNA and Tetryl,” J Amei Ckem Sot, 79, 32-37 (1957)
P Deneuville, C Gaudin, Y de Longueville and .I Mala, “Comparison of TATB and DINGU Explosive Properties,” Proceedings Seventh Symposium (International) on Detonation, Annapolis, MD, June 16-19, 1981, pp 540-546
Y De Longueville, A Delclos, C Gaudin and J Mala, “Influence of Inert Binders on Detonation Properties of Cast-Cured PBX,” Proceedings Seventh Symposium (International) on Detomtion, Annapolis, MD. Jnne 16-19, 1981, pp 560-565
A W Campbell, H L Flaugh, A Popolato and J BI Ramsay, “Customized Explosives Based on Plastic-Bonded Mixtures to TATB and HMX,” Proceedings %venth Symposium (Inteinationnl) on Detonation, Annapolis, MD, June 16-19, 1981, pp 566.574
V M Titov, V V Sil’vestrov, V V Kravtsov and I A Stadnitschenko, “Investigation of Some Cast TNT Properties at Low Temperatures,” Proceedings Sixth Symposim (InternationalJ on Detonation, Coronado, CA, August 24-27, 1976, pp 36-45
R J Spear and M G Wolfson, Determination ofDetonation Parameters of Booster Explosives at Small Diameter Charges, DSTO Materials Research Laboratory MRL-TR-89-45, Cordite Avenue, Maribymong, Victoria 3032, Australia (1990), from Defense Center Information Center, Ft Belvoir, VA, AL- A220 352, Ar-006-287 (1990)
44 M E Evans, B 0 Reese, L B Seely and E L Lee, “Shock Initiation of Low-Density Pressings of Ammonium Perchlorate,” Proceedings Fourth Symposium (International) on Detonation, White Oak, MD, Octobel 12.15. 1965, pp 359-311
45 A R Clairmont, Jr, I Jaffe and D Price, The Detonation Behavio? ofAmmonium Perchlorate as a Function of Charge Density and Diameter, U S Naval O?dnance Labomtoiy NOLTR-67.71, White Oak, MD (1967) p 24
46 M L Pandow, K F Ockert and H M Shuey, “Studies of the Diameter- Dependence of Detonation Velocity in Solid Composite Propellants,” Proceedings Foul th Symposium (International) on Detonation, White Oak, MD, October 12- 15. 1965. pp 96-101
47 D Price, A R Clainnont, Jr and J 0 Erkman, “Explosive Behavior of Aluminized Ammonium Perchlorate,” Combustion & Flame, 20, 389-400 (1973)
I-8
48 J D Renick, P A Persson and J A Sanchez, “Detonation Properties of Mixtures of HMX and Emulsion Explosives,” Proceedings Ninth Symposium (International) on Detonation, Portland, OR, August Z&September 1. 1989, I, 54s 552
49 H Eyring, R E Powell, G H Duffey and R B Parlin, “The Stability of Detonation,” Chem Rev 45, 69-l 82 (1949), s,me data taken from A Parisot and P Laffitte, Congr chim ind. Compt rend l&e congr, Nancy, pp Y30-936 (1938), also from MacDougall, uncited
50 G V Dimza, “Critical Detonation Diameter for an Explosive containing an Inert Additive,” Combustion, Explosives & Shock Waves (Russian) I2,216-218 (1976)
51 R Kb Kurbangalina and L I Patronova, “Effect of a Steel Sheath on the Critical Detonation Diameter of Condensed Explosives,” Combustion, Explosives & Shock Waves (Russian) 12, 587.590 (1976)
II. Comparing the Data
We now consider some simple comparisons
of the data Figure 1 shows a detonation
velocity, U,, -inverse radius plot, where the
widest possible spread of data has bee” taken
Infinite radius is at the left, moving to the right
ca”ses shrinking of the cylinder Ultimately, the
lines die o”t because of failure, ie the cylinder
no longer propagates the detonation because too
much energy is lost out the sides Large size
cylinders lie to the left, tiny ones to the right
PBLU ---s.
XTX- 8003
Failure Region
001 01 1 10 Inverse Radius, l/R, (mm-‘)
Fig 1 Detonation velocity vs inverse radius for the widest possible spread of explosive data
The most obvious thing about Fig 1 is the
huge spread “ver orders of magnitude It would
be nice to reduce to nornmlized coordinates The
most obvious choice for detonation velocity is
U,iD or 1 - U,iD, where D is the infinite radius
detonation velocity It is not possible, however,
to select a standard radius because there is no
overlap in many cases The only apparent fixed
radius is that for failure, Rf, but this is a fwction
of continement
From Fig 1, we see varying changes of
slope XTX-8003 barely changes its detonation
velocity before it fails, whereas the composite
explosives can detonate at extremely reduced
velocities
The same broad spread appears in Figure 2
when we plot the calculated reaction z”“e lengths
versus cylinder radius The short zones of XTX-
8003 lie at the lower left and the long zones of
HANFO at the upper right
[ 10 160 Radius, R, (mm)
Figure 2 The broad spread of calculated reaction z”“e lengths The smallest belongs to XTX- 8003 and the longest to HANFO
Figure 3 shows a family of TNT samples,
taken at various densities We see that adding
void volume increases both the reaction zone
length and the failure radius Also, the reaction
II- 1
zone length at a given density increases with
radius with a power between 0 5 and 1 0
o:- , I 0 5 1” 15 20
Radius, R, (mm)
Figure 3 Reaction zone-radius for a family of TNT samples of different densities All work was done by the same researchers The densities are listed
Many other effects appear Figure 4 shows
two high-HMX explosives PBX-9501 (95%)
and PBX-9404 (94%) The two cures overlie
each other but the different binders produce
different failure radii The binders are PBX-
9404- NC and CEF and PBX-9501- estane and
BDNPA-F
\ 1 I
PBX-9404 :
Figure 5 shows an inverse radius plot for
PBXN-111, the only explosive with comparable
confined and unconfhxd data The failure radius
is shorter for the unconfined data The reaction
zone lengths are about the fame The infinite
radius detonation velocities are the same
Figure 4 Inverse radius plot for two high-HMX explosives showing that binder affects the failure radius
II-2
Confined
I
I
I 0 0 05 01
Inverse Radius (mm-l)
Figure 5 Inverse radius plot of confined (solid symbols) and unconfined (open) PBXN-111 Data is from the U S Navy and Australia Confinement also decreases the failure radius
Figure 6 shows B dramatic reaction zone
effect in 70% RDX-urethane, where particle sizes
were carefully set and the explosive was pressed
near full density, so there would be almost no
hot spots This last feature makes this an
unusual explosive in the ranks of those listed in
this report The data is also different in that no
radius effect is seen The measurements were
unfortunately not extended to failure With radius
not a factor, the reaction zone lengths are roughly
given by
<xc> - 0 5 + 0 006d(pm) (1)
where d is the RDX particle size NM and liquid
TNT show a weak dependence on radius, so that
hot spots may be the cause of the radius effect
01 , I 5 IO 15 20 25
Radius (mm)
Figure 6 The reaction zone length varies dramatically in these 70%RDX-urethane samples with well-sieved sizes and almost no hot spots
II-3
r
Table 1 Detonatxon front curvature data.
Sectlo”
Quad- ratlc TATB Family
Quad- ram NM Families
Explowe
PBX-9502 PBX-9502 PBX-9502 PBX-9502 T2 LX-17 T2 PBX-9502 PBX-9502 EDC-35 EDC-35 EDC-35 EDC-35 EDC-35 EDC-35 NM NM NM NM NM NM-silica NM-silica NM-silica
Den- Rad- Edge Det Velocity CUNdUI~ Mea. Calc. sty 1”s Lag, talc. u, D fit parameters Edge Edge G RCUr K Len-
R, Lo <x2 (mm/ (mm/ h& (“4 (“4 (mm) P$ PS) ( “2
B Angle Angle (lls-’ li2A Wall (MWI gth ) (“d (de& (deg) *GPa-*) (mm) mat (mm) mm2) (mm)
1.890 6.0 0.78 14 7495 7 78 1.28E.02 5.69E-06 46 23 0.021 39 85 1.890 5.0 0.74 1.2 7455 7 78 1.68&02 1.91E-05 40 28 0.026 30 74 1.890 9.0 1.03 2.0 7.553 778 7.51E-03 6.58E-07 37 20 0.016 67 117 1.890 5.0 0.77 1 1 7458 7 78 1.64&02 2.17E-05 40 30 0.027 31 75 1.855 25 1.92 0.9 7 620 7 65 2.25E-03 2.08E-09 8 13 0.037 222 46 1.907 25 4 2.07 2.6 7.630 7 72 2.42E-03 1.91E-09 15 14 0.012 207 cu 2.7 136 305 1.855 50 2.92 1 1 7.633 765 9.23.E.04 4.38E-11 6 10 0.029 542 56 1.890 25 0 2.08 3.3 7.677 7 78 2.I@-03 2.77&09 42 15 0.009 246 199 1.890 25.0 2.18 3 4 7.672 7 78 2.21E-03 2.48E-09 31 14 0.009 227 192 1.904 5.0 0.8 7440 7 73 2.56&02 1.57&05 29 0.036 20 43 60 1.904 5.0 0 7 7440 7 73 2.30&02 3.59E-05 42 0.042 22 48 60 1.904 5.0 0.8 7440 7 73 2.27&02 2.98E-05 38 0.039 22 49 60 1.904 25 4 2.0 7.670 7 73 2.43E-03 1.24&09 11 0.016 206 98 762 1.904 25 4 1.9 7.670 7 73 2.51E-03 1.52E-09 13 0.017 199 95 762 1.904 25 4 2.0 7.670 7 73 2.60E-03 6.76E-10 10 0.016 192 91 762 1 118 6.35 0.21 0.2 6.199 6.21 4.36E-03 6.66&07 4 6 0.57 115 Br 2.0 7 1 118 254 0.54 0 7 6.205 6.21 6.76&04 5.52E-10 I 4 0.21 740 Py 2.0 21 1 124 18.42 0.85 0.3 6.230 6.24 9.50B04 l.l6E-08 12 10 0 40 526 Py 10 18 1 124 13 78 0.80 0.2 6.229 6.24 1.79&03 6.61E-OS 16 14 0.62 279 Py 10 11 1 124 9.57 0.86 04 6.208 6.24 6.32E.03 3.52&07 14 16 0.37 79 Py 1 0 13 1171 18.59 113 18 6.140 6.55 9.62E-04 1 74E-08 27 15 0.0077 520 Py 1 0 1099 1 171 9.57 0.99 4.9 6.128 6.55 5.96E-03 5.69E-07 19 21 0.028 84 Py 10 182 1.171 6.80 0.95 2.7 6.090 6.55 147E-02 2.86E-06 21 24 0.051 34 Py 1 0 80
NM-silica 1 171 5.26 0.98 2.5 5.800 6.55 2.99E-02 7.33&06 21 26 0.051 17 Py 1.0 61 Quad- 1 6 pm, mono 145 15 0.60 1 1 7420 7 45 2.51%03 3.15&09 4 5 0.035 199 42 mn ratlc 127 PI”, bl6 145 15 1 40 1.8 7.330 745 6.21E-03 8.48E-09 10 13 0.02.1 Xl 6T 200 RDX- 307 pm, bl 6 145 15 2.00 4.5 7.030 745 8.92E-03 6.87E-09 15 17 0.008 56 156 200 urethane 428 pm, mono 145 15 5.00 6.870 7 45 2.57E-02 NA 35 38 19 200
T-1
SectKJn
Misc.
Table 1, page 2 Exploswe po Ro Lo xe U, D A B Angle Calc. G Rcu mat (mm) K(A) L ref
PBX-9404 1.840 12.7 0.46 1.9 8.750 8.80 l.OlE-03 5.68&08 16 8 0.012 495 254 3 QUXk~tlC LX-04 Homo- and LX-04 Heterc- LX-04 geneous LX-04
PBXN-110 m-1 PBXW-131 PBXW-131 TNT pressed Ult. TATB NQ Comp B Comp B Octal RX-OX-HD RX-52-AD RX-52-AE Pentolite AP, 15 ~“m AP, 9 pm
1.854 12.7 0.53 1.0 8.455 1.853 12.7 0.54 2.1 8.420 1.863 12.7 0.58 0 4 8.476 1.863 12.7 0.59 0.3 8.480 1.680 24.95 2.35 8.390 1430 25 2.38 4.X 7491 1740 25 4 0.96 8.644 1 740 25 4 1.01 8.652 1.621 12.7 0 49 6.915 1.808 12.7 1.02 7.503 1.66 12.7 143 8.032
1.670 25 43 174 0.3 7.860 1.670 25 43 1.85 0.3 7.860 1.809 12.7 0.61 1 7 8.415 1718 12.7 115 8.147 1770 25 4 169 7.546 1780 25 4 173 7.570 1.560 254 570 7 190 0.927 26.04 4 14 3.390 1.020 25.0 4.72 6 3 600
8.49 8.49 8.49 8.49
7 67
7.87 7.87 8.49
3.80
1.58E.03 6.22E.08 2.18E-03 3.32&08 1.3 1 E-03 7.65&08 2.1 PE-03 4.84B08 2.04E.03 4.22&09 2.42E-03 3 74&09 l.O2E-03 6.46E-10 2.07E-04 2.57&09 1.82&03 4.12E-OX 3 76&03 7.97E-08 7.24&03 5.9lE-08 2.40E.03 1 43E-09 2.48&03 S.OOE-10 2.24&03 6.97&08 7.21&03 not used l.PlE-03 1.54E-09 1 73E-03 2.31E.09 8.88E-03 not used 6.47&03 not used 6.65&03 7.25E-10
9 14 16 12 24 21 26 38 16 18 23 9
12 11 12 13 13 22 17 33 51
9 7
10 9 19 19 5
10 7 14 10 12 10 11 10 11 13 24 19 21 41
0.025 0.013 0.063 0.099
CU 3.2 105 CU 3.2 151 CU 3.2 51 CU 3.2 22
305 305 305 305 178
0.0080
316 229 382 228 245 207 490 2413 274 133 69
20x 202 223 69
262 289 56 77 75 49
0 108 0 104 0.015
73 cu 51 cu 51 CU 3.2 CU 3.2 cu 31
19 SS 12.7 18 CU 2.6 166 CU 3.2 cu 2.7 CU 2.7
cu 40
1 1 1 1
16 17 I 1 1 1
508 508 289 305 298
305 305 305 305
0 173
14 14 1 1 1 1
16 1
19 19
1067 229 114 AI’, 26 pm 1435 254 5.93 2.400 l.O3E-02 5.30E-09
Quad- PBXN-111-N 1 790 24.22 2.85 7 5.611 5.90 4.63E-03 9.86&IO 16 15 0.0056 108 Br 171 59 305 8,15 mtlc PBXNlll-N 1 790 33.96 4.00 5 5 757 5.90 2.90E-03 3.52E-10 15 16 0.0077 172 Br 7.3 48 305 8 PBXN- PBXN-I 11-A 1 79 12.60 1.60 10 5.130 5.96 975&03 1.98E-08 19 16 0.0037 51 Br 5 1 73 177 9 111 PBXN-111-A 179 18.94 2.10 12 5406 5.96 4.86B03 7.81&09 19 17 0.0033 103 Br 50 102 217 9 Families PBXh-111-A 179 23 49 2.50 12 5.513 5.96 3.68E.03 345E-09 20 18 0.0033 136 Br 5 1 111 253 9
PBXi’-111-A 179 50.00 20 5 747 5.96 l.O6E-03 4.27E-11 9 11 0.0021 471 Br 50 378 9 PBXN-111-N 1790 34 12 574 7 5.572 5.81 3.57E-03 l.OOE-09 25 28 0.0061 140 64 305 8,14 PBXN-111-N 1 790 24.01 4.75 8 5.309 5.81 X.21&03 2.66E-09 25 28 0.0051 61 56 305 8,14 PBXN-11 I-N 1 790 20.52 4.29 9 5 158 5.81 8.49E.03 1.15E-08 22 31 0.0044 59 68 305 8,14 PBXN-111-N 1 790 24.06 4.87 8 5.311 5.81 6.46&03 6.16E-09 27 31 0.0047 77 71 305 8,14
T-2
Table 1, Page 3 Sectmn Explowe P0 R, L, xe Us D A B Angle Calc. G Rcu mat (mm) K(A) L xf
PBXN-111-N 1790 2045 4.81 8 5 154 5.81 9.58E-03 1.24E-08 29 33 0.0047 52 61 30s 8,14 PBXN-111-A 1 79 49.95 6.60 17 5.688 6.04 1.58E-03 178E-10 31 26 0.0024 317 208 378 9 PBXN-111-A 179 34.13 5.60 14 5.527 6.04 3.38E-03 l.l3E-09 29 29 0.0029 148 138 306 9 PBXN-111-A 179 24.06 5.00 11 5.313 6.04 6.50E-03 6.24E-09 33 32 0.0034 77 98 367 9 PBXi’-111-A 179 24.01 5.30 11 5.312 6.04 7.19&03 6.39E-09 40 33 0.0037 70 89 329 9 PBXh-111-A 179 20.45 4.90 10 5 186 6.04 9.62&03 1.27E-0X 32 34 0.0039 52 76 326 9
Ouad- ANFO-SW I 16 6.8 10 3 740 5.88 2.47&02 173E-06 26 0.0061 20 130 700 10.11 ratlc ANFO Famihes
ANFO-SW 1 16 8.5 9 4.350 5.88 2.0lE-02 6.76E-07 28 0.0082 25 132 700 10;11 ANFO-SW 1 16 10.6 9 4.530 5.88 1.58&02 3.53E-07 32 0.0081 32 155 700 IO,11 ANFO-SW 1 16 10.85 10 4.530 5.88 1.63E-02 8.85E-OX 23 0.0073 31 150 700 10,ll ANFO-SW 1 16 16.8 2.80 7 5.370 5.88 8.35&03 1.89E-08 22 23 0.013 60 131 700 IO,11 ANFO-SW 1 16 19.0 7 5.350 5.88 8.19&03 9.63E-09 24 0.012 61 138 520 10,ll ,ANFO-SW 1 16 2X.3 10 5 450 5.88 4.65E-03 1.39E-09 23 0.0087 108 201 600 10,ll ANFO-SW 1 16 39.3 9 5.640 5.88 2.74&03 4.lXE-10 24 0.0107 182 197 600 10,ll ANFO-NM 1.248 2045 4.05 20 4.870 6.46 8.19E-03 8.28E-09 21 27 0.0040 61 PVC 3 7 373 762 12
IANFO-NM 1.248 38.95 7 15 23 5.580 6.46 3.84E-03 378E-10 20 27 0.0040 130 PVC 5.5 505 915 12 ANFO-NM 1.248 51 15 8.67 23 5.840 6.46 2.66B03 8.77E-11 19 25 0.0042 188 PVC 6.0 537 1220 12 HANFO 1.061 60.05 13.00 65 2.900 442 3.08E-03 1.2lE-10 24 43 0.0010 162 Cb 10 711 1000 9 HANFO 1.061 76.35 17.30 68 3.280 442 2.52&03 I77E-11 26 33 00011 198 Cb 1.0 738 1000 9 HANFO 1.069 126.8 29.80 12 4.300 442 1.58E-03 8.8X&13 32 30 0.0079 316 Cb 1.0 162 1000 9 HANFO 1070 40.2 12.20 2.386 442 Cb 10 1000 9
Quad- IIRX-3A 1.580 25 1.87 3 7 787 787 2.82E-03 3.36E-10 19 9 0.024 177 44 17 ratlc QMlOOR 1.509 SO.8 2.91 13 7429 7.59 9.91%04 3.llE-11 9 9 0.004s 505 Cu 106 477 1016 1 Misc. QMlOOR 1.509 50.8 3.29 12 7 420 7.59 1.26B03 X.23E.12 14 8 0.0048 397 cu 10 6 396 1016 1 comp- PBXW-126 1.800 50.8 3.00 6.470 8.8OE-04 4.24E-11 8 10 568 Cu 106 1016 I os1te Rx4 1.500 25 3 76 16 5.620 6.42 3.83E-03 6.47E-09 30 30 0.0023 131 274 178 16
PBXW-123 1.920 38.5 6.55 5.560 3.69E-03 6.26&10 21 31 136 Br 64 152 18 Non- PETN 1743 12.7 0 10 8.201 NA 2.36E-0X 3 3 CU 3.2 305 1 QU&dlC LX-14 1.825 12.7 0 16 8.778 NA 4.llE-08 4 5 CU 3.2 305 1
HM.X 1739 12.7 0 19 8.550 NA 3 72E-0X 7 4 CU 305 1 LX-10 1.87 25 4 0.26 8.820 NA 8.93E-10 6 3 CU 6.1 305 1 LX-04 1.X7 25 4 0.39 8.470 NA 1.5lE-09 7 5 CU 6.1 305 1
T-3
Table ?.a Size Effect Data for Pure and Heterogeneous Explosives
P”@ 1 HOMOGENEOUS EXPLOSIVES- TNT
Radius Us talc G Radius Us talc G Ro (mm/ <xe> (P-I* Rcur Ro (mm/ <xe, Us-I’ Rcur
(mm) ps) (mm) ma-2) (mm) (mm) ws) (mm) GPa-2) (mm) Liq TNT - 6 57 19 4 TNT m 6 84 17 0 I 44 g/cc, 756 655 41 0014 1068 pressed 39 09 683 IO 0 817 1oooc 47 5 653 35 0016 572 unconf 3909 682 16 0 05 634 unconf 350 652 3 1 0018 381 156 1953 683 05 0 16 408 ref 21 325 652 31 0018 344 g/cc 1302 681 07 0 11 180 TNT - 475 57 ref 20 976 680 07 0 11 122 oressed 3908 471 34 0 14 434 TNT w 6 84 180 conf 0 90 i953 466 30 0 16 164 prtssed 3907 683 :0 0 07 817 g/cc 1302 463 24 0 19 98 conf 1953 683 04 0 17 449 ref 20 980 459 23 0 20 66 160 1302 683 05 0 14 220 TNT ca 522 75 ref 20 976 682 05 0 14 141 oressed 3908 518 33 0 09 442 TNT m 691 18” z conf 1953 5 13 28 0 II 169 pressed 39 09 6 907 05 0 14 1134 1 05 1302 5 IO 23 0 13 102 unconf 3909 6910 414 ref 20 980 505 22 0 13 68 161 1953 6903 04 0 16 427 TNT 5 69 96 g/cc 1302 6907 02 0 42 378 pressed 3908 566 25 0 08 502 ref 20 976 6902 02 0 29 204 canf 1953 562 22 0 09 189 TNT - 695 189 I 20 13 02 5 60 18 0 II 1 13 pressed 39 12 6 930 17 0036 605 ref 20 980 557 17 0 12 78 unconf 39 09 6 942 0 9 0066 820 TNT 6 01 11 3 1 63 3909 6941 10 0061 791 pressed 3908 598 24 0 063 514 g/cc 3630 6928 17 0036 544 canf 3908 599 19 0 078 573 ref 20 1955 6927 10 0065 288 1 30 1954 596 19 0 079 205 1955 6944 04 0 16 451 g/cc 1954 595 19 0077 201 1303 6941 03 0 18 263 rcf 20 1303 593 17 0089 118 13 02 6929 06 0 10 198
13 03 5 93 16 0090 120 1270 6926 06 0 10 I85 976 6933 04 0 16 159 976 6937 03 0 19 175 7 62 6 924 0 4 0 15 108 5 45 6 922 0 3 020 75 423 6 905 0 3 019 50
ref 20 3 47 6 906 0 3 024 4, TNT - 649 14 3 TNT - 694 19 0 pressed 39 12 6469 19 0 05 582 pressed 39 12 6941 414 conf 3908 6466 21 0 05 556 conf 1955 6938 019 0 33 651
976 6398 13 0 08 88 b80 125 398 97 006 47 TNT - 670 16 0 g/cc 10 0 384 85 007 35 pressed 3909 668 I7 0 05 605 unconf 70 339 73 007 22 unconf 3909 668 15 0 05 643 <385p’m 5 0 282 64 006 15 151 1953 666 14 0 06 240 ref 37 45 220 68 005 12 g/cc 13 02 6 64 12 0 07 140 40 187 65 004 10 ref 20 976 663 II 008 96 35 failed TNT m 6 75 16 0 pressed 3907 674 08 0 II 895 canf 1953 674 05 0 18 407 I 53 1302 672 07 0 11 178
ref 20 976 673 04 0 21 158 I .
T-5
Table *a, page 2 TNT OTHER HOMOGENEOUS EXPLOSIVES
Ro Us <xe> G RCUI Ro Us <xe> G Rw TNT - 5 23 70 TNT m 7 09 194 pressed 1500 471 71 0 04 71 cast 29 0 700 35 0 274 1 00 1000 453 58 0 05 43 unconf 20 0 698 28 0 02 176 g/cc 750 418 57 0 05 28 77 K 17 5 700 2, 0 03 165 unconf 5 00 394 43 0 06 17 ref 42 16 0 699 2, 0 03 144 <3x5 k’m 4 50 3 44 4 8 005 14 15 0 697 2, 0 03 131 ref 37 4 00 failed 12 5 696 19 0 03 103 TNT 6 70 14 5 100 692 I8 003 76 pressed 20 0 655 35 0 03 156 90 688 19 003 64 1 46 159 650 34 0 03 113 80 686 I8 003 55 g,tX 10G 653 i 9 0 05 75 70 682 17 003 46 unconf 7 45 645 18 005 49 60 678 16 004 37 <385pm 5 10 639 14 007 31 50 674 15 004 30 ref 37 4 09 633 13 007 24 40 675 12 005 24
3 08 612 13 0 07 15TNT m 7 08 19 4 2 58 596 13 0 07 12 cast 28 0 698 36 0 02 252
pressed 1000 685 1 I 55 750 67
IF& 5 00 674 10 0 08 37 I 90 690 17 003 68 unconf 4 12 612 09 009 29 80 689 16 004 60 <385 hrn 2 58 660 07 010 16 70 684 16 004 47 ref 37 1 94 650 07 011 11 60 676 17 003 37
1 58 634 07 011 8 TNT 7 08 20 5 pressed 15 00 7 00 11 0 03 147 I 62 1035 7 00 1 1 0 05 101 g/cc 7 55 698 10 005 69 unconf 510 698 07 008 46 <385pm 4 12 694 07 008 34 ref 37 3 10 686 07 008 22
2 08 615 06 009 I3
TNT 6 96 19 4 cast 28 0 691 23 0 03 323
20 0 6 90 1 9 0 03 208
T-h
1 I
F c 0
8 6 r,
P ” 1
g c 1 2 T,
P ” 0
g c 3 4 r<
R ” 1
g, I w I[
R “: 0 rc
‘able 2a. page 3 IOMOGENEOUS EXPLOSIVES
Ro Us <xe> G Rcur ‘ETN - 5 277 78 onf 8 25 514 16 017 61
95 7 00 506 18 015 45
/cc 7 00 511 15 018 49 55 pm 5 70 50’ ‘7 016 34 ef 28 5 70 502 17 016 34
3 81 488 15 017 20 3 81 486 15 017 20 2 03 456 ‘2 02’ 9 2 03 458 12 02’ 9 2 03 460 11 622 9 2 03 458 I2 021 9
‘ETN m 5 53 86 nconf II 10 557 157 00 9 50 550 07 0 34 113
+o 01 9 50 547 1’ 023 94 /CC 7 95 542 13 018 65 OrI us 6 35 540 11 021 49 50. 4 77 540 09 027 37 10pl 4 77 537 10 023 34 :f 38 3 I8 529 09 026 20
3 18 5’8 ‘1 020 I7 I 59 510 06 035 8 I 59 494 08 027 7
‘ETN - 5 53 79 nconf 12 70 523 40 007 74 96 9 50 520 32 008 53
+oo, 7 95 541 13 021 64 ICC 6 35 527 18 015 39 on us 6 35 5.35 14 019 44 oo- 4 77 529 I3 021 30 20 Km 4 77 531 12 022 30 :f 38 3 18 517 II 024 17
3 18 513 12 022 17 DX - 6 69 14 5 nconf 1270 624 46 002 69 I9 11 10 638 3 I 003 68
to 04 II IO 642 29 003 71 kc 9 50 643 24 004 61 50-210 9 50 641 25 004 61 m 7 95 6 70 58 :f 38 7 95 644 20 005 53
6 35 6 83 47 6 35 6 83 47 4 77 660 06 018 45 4 77 649 10 010 34 3 18 644 08 013 21 3 18 647 07 0’4 22 1 58 588 08 011 7 I 58 571 10 009 7
DX - 583 82 nconf 3 45 550 ‘1 024 20 90 g/cc 2 83 550 09 028 ‘6 :f 49 2 28 533 10 026 1’
1 78 520 09 028 8 1 76 505 10 024 8
R
T
” 0
T “I 0 L! & 31 4( re
Ro Us <xe> G RCUl DX 14’ 509 08 031 6
‘etryl w 5 86 77
nconf 3770 577 5 ?-f%- 342 94 21 95 528 IO 0 03 105
+o 02 15 90 486 II 002 64 /cc 1270 525 6 005 60 oo- 1270 527 6 005 61 40 w*m 1270 497 8 003 53 :f 38 1270 502 8 004 53
11 II 5 16 6 005 50 ‘11’ 507 6 004 48 III’ 493 7 004 46 11 1’ 497 7 004 46 953 534 4 007 47 953 502 6 005 40 9 53 4 84 7 004 37 795 452 7 004 29 635 428 6 004 21 635 434 6 004 22 4 67 I 52 8 001 ‘1 4 67 199 8 00’ 12 467 201 8 001 12 3 18 failed
my’ cs 5 85 83 nconf 3770 561 10 -i???- 24’ 98 3770 544 ‘4 .o 03 3150 560 9 ‘cc 3150 566 7 30. 2520 576 3 IO pm 25 20 5 59 7 zf 38 21 95 5 67 5
21 95 5 73 4 1590 533 7 1270 533 6 1270 510 7 1270 520 6 II ‘1 495 7 11 II 497 7 1111 519 6 II 1’ 5 12 6 953 542 4 953 507 5 953 5 15 5 7 95 536 3 7 95 545 3 635 538 3 635 527 3 467 5 ‘9 2 467 523 2 467 482 3 4 67 5 04 3 318 488 2 1 59 failed
0 02 202 0 03 199 0 04 216 0 08 225 0 04 156 0 06 156 0 07 174 004 78 004 62 003 56 004 58 003 46 003 46 004 51 004 49 007 51 004 41 005 43 007 40 009 43 010 33 008 30 010 21 011 22 007 18 009 20 0” 13
1 T-7
Table 2% page 4 I HOMOGENEOUS EXPLOSIVES
Ro Us <xe> G RCW ADNBF m 8 23 25 3 E 171 298 781 09 0 04 ‘8 c
1 g/cc 203 772 07 006 1’ uncanf 101 709 06 006 4
638 742 09 005 55 298 741 04 0’1 25 203 745 03 019 19 203 731 04 011 14
638 762 12 003 49 298 754 07 006 20 298 758 06 007 21 203 746 06 007 I3 101 679 06 006 4
DNBF m 765 25 5 1 69 203 752 03 013 18 g/cc 101 748 02 021 8 unconf 076 733 02 018 5 ref 43 2.4. - 433 48 DNT 1000 389 5 011 47 unconf 800 378 4 012 36 0 95 625 359 4 012 25 g/cc 5 00 3 27 4 011 17 ref 313 288 3 012 IO 36 250 245 3 011 7 DINGU - 45 48 unconf 30 40 15 004 138
r3; 6 67 3 0018 28
Ro Us <xe> G RCUl IM - 6210 119 onf 4763 6210
u: I i g, 1, 2 re
I
033 1270 6201 04 039 247
/cc 1269 6200 04 037 238
3oc 6395 6188 03 043 92 sf 22 6350 6190 03 046 94
3’65 6169 02 057 37 3215 6 166 03 053 37 ‘525 6 125 02 072 14 1500 6128 02 075 ‘4 I21 faikd
IM - 6236 II 9 L
nconf ‘842 6233 02 0 57 517 ‘30 ‘842 6227 05 0 27 360
ICC 1546 6233 02 0 67 434 :f 4 1378 6228 04 0 39 279
1370 6229 03 0 43 291 1106 6226 03 0 42 208 967 6220 04 0 35 156 958 6221 04 037 157 957 6 196 07 0 I9 113 8 63 6212 05 0 30 120 8 33 6199 06 0 23 10’ 8 32 6220 03 0 41 134
DNA - 62 94 nconf 9945 613 980 00 9945 6 ‘6 1’73
9 03 9945 kc 9945 50. 99 45 IOpm 99 45 :f 38 3770
3770 1270 I2 70 ‘1 10 11 IO 950 950 795 7 95 635 6 35 4 77 4 77 3 ‘8 3 18 356 4 003 9
DNA cs 6, 95 1conf 1270 549 6 003 60
608 I6 0 014 8’0 6 13 971 5 70 512 575 532 638 277 630 277 543 7 003 56 552 6 003 58 532 7 003 47 538 6 003 48 516 6 003 38 537 5 004 41 537 5 004 34 545 4 005 35 534 4 005 27 547 3 006 29 499 4 005 18 521 3 006 20 414 3 004 IO
99 1270 544 6 003 58 002 12 70 561 5 004 65
'cc 1270 568 5 004 69 lo- 1110 514 7 003 46 !O wrn 1110 539 6 003 50 f 38 II IO 556 5 004 54
,110 564 4 005 58
T-X
T:
H
E “I
I 0
w “1 3’ 4:
able Za, page 5 ‘OMOGENEOUS EXPLOSIVES
Ro Us <xe> G Rcur DNA 9 50 539 5 004 43 1conf 9 50 532 5 004 42 99 9 50 556 4 005 46 ‘cc 9 50 558 4 005 47 wmf 7 95 500 6 003 31 70. 7 95 522 5 004 34 LO pm 7 95 547 4 005 37 f 38 7 95 534 4 004 35
6 35 52’ 4 005 27 6 35 477 5 003 24 635 520 4 005 26 6 35 524 4 005 26 4 17 409 5 003 15 4 77 486 4 005 18 4 77 486 4 005 18 4 II 498 3 005 19
unconf IO 765 15 003 85 zl<n,,m 0 7 LO 1 n 004 87 ~._” rl..
ref 25 NT0 I 84
, , “, . ” ”
7 failed - 8 42 28 6 14 8’9 3 0 011 102
741 7 nnt7 40 - 8 23 286 172 1 85 20 809 3 0011 :
g/cc ‘4 812 2 0 018 129 unconf 10 802 2 0017 75
&lconf 1446 817 1 0 022 150 250 pm ‘288 8 14 2 0 021 121 LANL 12 68 8’4 2 0 02’ 121 ref 24 ‘2 70 failed picric - 5 25 62 acid 8 57 492 3 0’4 47 0 90 g/cc 4 35 458 2 016 19 unconf 3 90 442 3 015 16 ref 49 3 06 432 2 0’7 ‘2
2 48 406 2 0’7 9 2 08 408 2 020 7 2 03 369 2 016 7 1 52 248 2 010 4 I 36 223 2 009 4
Ro Us <xe> G Rcu,
T-9
Table Za, page 6 I I HETEROGENEOUS-<20% BINDER
Ro Us <xe> G Rcur Ro Us <xe> G Rcur XTX- - 7 307 ‘8 NM 477 4916 4 003 I8 8003 102 7 248 0 09 0 8 II 2 silica last one failing 1 53 045 7 244 0 04 I I 48 X-0219 m 7 684 26 3
g/cc 026 7161 004 17 21 uncanf 25 40 7 555 4 0010 220
g/cc 423 8236 04 010 47 795 7380 2 0017 52 ref 22 318 8213 03 01’ 32 7 00 failed
2 54 8 172 0 3 0 10 22 EDC-35 m 7 72 27 5 212 8143 03 011 18 1 90 63 50 7 690 3 5 0009 886
PBX- - 8 805 34 5 g/cc 2540 767 27 0012 300 9404 73 00 8 800 I I 002 ,941 ref5, 25 40 7 639 2 7 0012 255 unconf 73 00 8 803 0 6 004 2631 29 1270 7586 19 0017 108 1 83 1905 8789 06 0 04 342 635 7485 14 0 023 45 g/cc 1270 8774 06 0 04 ‘84 5 00 744 12 003 33 ref 22 1270 8775 06 0 04 185 EDC-35 es 7 92 27 5
I 00 8 525 02 010 I ““Kmf 25 00 7 664 3 3 0010 221 075 8355 02 010 4 I 890 25 00 7 667 3 3 0010 225 0 64 7 874 0 3 007 3 20 003 1575 1624 26 00’3 128
r
I 83 1270 8792 06 0 04 191 450 7456 12 003 28 g/cc 251 8728 03 009 25 4 25 742 ‘2 003 26 Fef 22 142 8612 03 0 09
IO’ 8487 02 0 09
I g/cc ref I I7 4 680 6 895 74 6113 6086 6093 14 12 12 01’ 0 013 13 73 52 52 ref 3 26 002
663 6071 13 012 49 581 5978 ‘5 0 IO 37 I-- PBX- 578 5973 ‘5 0 10 37 9502 5 50 5 777 2 1 007 29 -55oC 543 5818 20 008 29 unconf 543 5893 17 009 31 1891 543 5854 19 008 30 io 002 53’ 5872 I8 0 09 30 ref 26
5 00 7477 400 7 439 300 7377 failed
- 7691 25 00 7 67 25 00 7 665 ‘650 7616 900 7546 7 15 7485 600 7465
I 1 003 34 IO 003 26 08 004 19
27 5 11 0030 392 12 0026 367 17 0019 170 14 0023 75 14 0022 53 13 0025 43 I 5 507 527 26 5772 5 5399 869 21 29 18 007 009 005 28 30 22 5 525 50 7 7398 424 1 13 3 0024 0024 31 34
T-II?
Table *a, page I HETEROGENEOUS-<20% BINDER
Ro Us <xe> G Rcur Ro Us <xc> G Rcur EDC-35 - 7 76 27 5 70% 7 45 15 SLAB 100 762 24 0 014 67 RDX- 25 0 7 44 0 67 0 16 497 unconf 5 0 756 15 0 021 30 urethane 15 0 7 42 0 84 0 13 207 LX-17 m 7 7’3 26 8 145 p/cc 100 741 0 67 0 I6 ‘26 conf 254 762, 29 0012 244 6um 75 7 38 0 73 014 78 ref I 127 7528 23 0 0’4 97 rei 6, 7 5 0 7 37 0 54 020 50 T2 - 7646 21 70% m 7 45 15 unconf 50 7 633 I6 0 02 92, RDX- 24 0 131 2 61 0 04 238 ref 13 25 762 I2 0 03 364 urethane 14 8 7 33 2 ‘3 0 05 128 RDX - 8 50 22 8 145 p/cc 9 9 7 22 2 18 005 70 94 61 6 38 759 32 0 015 30 127&m 75 I I2 2 08 005 46 Pew 638 757 32 0 014 30 70% ce 7 45 15 unconf 296 610 28 0013 IO RDX- 25 0 7 39 2 2’ 0 275 156 g/cc 2 00 fail urethane ‘5 0 7 22 3 25 0 03 105 ref 43 I 45 gicc IO 0 6 84 4 15 002 5’ RDX = 8 50 24 0 134pm 97 81 6 38 196 22 0 020 35 70% - 7 45 15 Pew 2 96 738 17 0 024 13 RDX- 24 2 7 32 3 52 0 03 210 unconf 2 00 648 ‘7 0021 7 urethane 15 0 7 03 4 90 002 85 I56 g/cc I 54 544 17 0018 5 I 45 g/cc
IRDX - 8 49 26 9 197 8/
170% m 7 45 15 6 35 830 II 0 03 50 IRDX- 24 2 7 27 4 37 -5-E 7 187
Pew 6 35 825 I3 0 03 46 urethane ‘4 9 6 87 6 00 002 77 unconf 2 96 8 04 0 9 0 04 17 145 e/cc 1 64 g/cc 2 00 797 07 0 05 I I 428 pi ref 43 I54 789 06 006 8 72% ce 8 I7 ‘55
1 01 72, 06 005 4 RDX- 100 7.88 2 40 004 67 RDX - 8 58 29 7 urethane 9 0 784 2 35 004 58 97 8/ 2 96 8 47 0 31 0 08 27 no3 90 7 79 2 57 004 55 Dew 2 96 8 48 0 33 0 09 29 ref 40 90 7 94 I 84 006 65 unconf 2 00 846 026 012 ‘8 75 I 84 1 96 005 48 17’ g/cc 10, 8 29 0 23 013 7 75 7 87 I 83 006 50 ref 43 50 7 61 I 83 006 27
72% 7 73 15 5 RDX- 15 0 7 39 4 I2 --6-E- 93 urethane 150 7 46 3 56 0 03 101 no 5 100 7 44 2 44 004 66 ref 40 ‘00 751 2 04 005 72
90 751 I 86 005 65 75 7 35 2 22 004 45 75 7 42 1 93 005 48 50 7 0’ 2 25 004 25
T-l 1
‘able 2b Size Effect Data for Binary and Composite Explosives BINARY EXLOSIVES I
PW 1
Ro Us <xc> G RCUI Ro Us <xe> G Rcur !ompB - 7 92 26 8 Octal ce 8 472 32 2 ‘YPe I 1275 7 868 10 0 04 149 uncanr 2540 8452 IO 0 03 418 400um 12 75 7 887 07 0 05 175 11 82 1906 845 08 0 03 305 .DX 71
/cc :f 23
1240 7869 09 0 04 I46 g/cc 1145 8415 09 0 03 134 1240 7864 IO 0 03 143 ref 22 1145 8421 08 0 03 144 1240 7847 12 0 03 130 815 8402 07 004 89 635 7816 08 004 59 815 84 07 003 88 635 7819 08 005 59 636 8357 08 003 59 500 7787 07 005 43 317 8161 08 003 21 5 00 7 792 0 7 0 05 44 x-0341 c.3 1 82 7.8 1 5 00 7 755 0 8 0 04 40 19Oglcc 25 0 175 24 001 265 424 7738 08 0 05 33 unconf 9 0 764 16 0019 69 4 24 7 742 0 7 0 05 33 ref 41 45 748 12 0025 28 398 7738 07 0 05 31 HMX 40 741 12 0024 23 398 7725 07 0 05 30 15~rn 398 7746 07 0 05 32 TATB 3 18 7648 07 0 05 22 60wm 318 7650 07 0 05 22 X-0342 ca 7 87 28 5 2.81 7572 08 0 04 18 1 90 g/cc 25 0 782 19 3-r 296 281 7561 08 0 04 18 unconf 9 0 772 14 002 73 255 7476 08 0 04 15 ref 41 45 759 11 003 30 254 7416 08 004 14 40 756 10 003 26
214 6709 13 0 02 9 lref 41 45 770 09 003 33 2 14
_I “*
375 7372 14 0 02 20 ref 4j I 54 633 10 007 6 375 7458 I2 0 03 21 PBXW-7 - 192 23 0 358 7233 15 0 02 I8 TypeII 6 38 778 09 005 54 360 7268 15 0 02 19 1 70 g/cc 6 38 769 I3 0 04 46 356 1369 13 0 02 19 unconf 6 38 789 03 015 94 356 7273 I5 0 02 I8 ref 43 2 96 749 09 005 I7
yclatol w 8208 29 4 2 96 740 II 004 16 - 1conf 5080 8 217 2 96 760 08 006 19 74 25 40 8 204 2 01 740 07 006 I1
3 20 7 664 12 0 02 I7 ““&f 1000 778 I3 0030 89 2 80 failed ref 43 6 35 770 12 0 033 47
T-17
Table 2b, page 2 COMPOSITES - ANFO
Ro Us <.xe> G RClX QM-100 - 6 53 10 unconf 15240 629 37 0006 1008 1 26 7620 605 29 0 007 407 g/cc 5080 581 26 0 008 233 ref I, 3810 558 23 0 008 159 35 3048 538 21 0 009 120
2540 5 IO 20 0009 92
1905 462 18 0009 62 NFO - 5 88 92 w 4400 562 12 0 017 272 ,conf 4400 561 12 0 017 269 I6 3930 564 10 0 021 251
‘cc 2830 545 1, 0 019 15, f 10, 2400 538 IO 0 020 120 I 1900 535 8 0024 93
1700 52, 9 0022 76 1700 507 10 0019 74 1680 537 7 0028 84 1085 453 9 0019 39 1060 453 9 0020 38
3030 1917 50 0 003 77 2900 1932 47 0 003 74
1025 465 8 0022 37 10 25 4 74 8 0024 39 X0-20/6 375 498 38 b 123 8 50 432 8 0021 29 I41 g/CC 315 423 38 0002 94 850 438 8 0 022 30 fresh 25 0 fail 6 80 374 8 0019 21 unconf 19 0 fail
Ro Us <xe> G RC!l .NFO cs 4 74 46 80 s/cc 1460 456 36 0019 944
nconf, 1460 455 38 0018 933 :f 32 510 389 36 0016 200
25 5 3 25 26 0019 81 IANFO - 5 350 62 069 1268 4302 94 0004 487
5 ICC 9240 3 732 92 0 003 302 :f 9 9240 3512 100 0003 285
76 35 3 277 89 0 003 228 6005 2904 78 0003 174 5040 2581 7, 0003 139 5040 2 657 70 0 003 141 4485 2364 67 0003 123 40 I5 2386 60 0003 110 35 10 2288 53 0004 9, 35 IO 2164 55 0003 90
T
6 50 367 7 0 019 2” Id 74
3937 427 12 0 028 3679 430 10 0 033 3515 416 14 0 023 375 605 9 0009 251 3125 406 15 0 022 IO 0008 179 3005 413 12 0 026 250 591 8 0010 142 2660 408 I2 0 026 190 577 8 0010 98 2401 397 13 0 024 21 17 3 84 13 0023 90 19 11 376 13 0023 77
750 726 2, 0 004 463 625 722 19 0005 374 500 706 19 0004 265 375 706 14 0 006 200 315 668 17 0005 139 250 635 17 0005 100 190 620 14 0005 75 160 605 12 0006 60
mnf 2625 5 275 19 0 010 102 125 552 12 0006 43 f I2 2045 4862 IS 0010 71 95 fa ii-
15 95 4 044 18 0008 49 K-HO - 5 5 12 5
486 34 8438 52 27 0 004 cc 8438 4 78 0 001 285 1
6250 44 47 0 002 238 F1.31 5080 failure
Table 2b, page 3 COMPOSITES - ANFO
Ro Us <xe> G Rcur 1 Ro Us <xe> G Rcur QM-IOOR - 7 74 16 5 HMX20, - 7 59 15 5 60-40/B 625 715 25 0 003 328 emulsion 2745 545 26 00028 95 I 48 g/cc 60 days old unconf ref 34
125 529 13 0005 40 emulsion 2804 696 IO 00077 154 OM-IOOR m 7 86 17 2 un&conf I3 44 6 25 9 00077 55
Lo-4016 37 5 706 18 0004 177 151 g/cc !3 44 60! !O 0 0066 5! I 47 g/cc 315 668 20 0004 130 rcf 48 10 93 632 7 00101 46 fresh 250 668 I6 0005 103 9 2, 617 6 00106 37 unconf 190 591 17 0004 66 8 22 585 6 00097 31 ref 34 160 591 I4 0005 56 7 09 502 7 00073 23
125 fail 6 14 510 6 00088 20 QM-IOOR - 7 62 17 2 5 51 340 8 00045 15 60-4016 375 706 14 0005 200 4 96 253 8 00033 12 I 50 g/cc 315 668 17 0004 139 5 00 failed 60 davs 250 651 15 0005 105 HMX40. w 7 51 196 old 190 620 I4 0005 75 emulsion 1344 708 4 0013 76 unconf I60 605 I2 0 005 60 un&conf 6 29 664 3 0017 28 ref 34 125 fail 1 55 g/cc 6 32 652 4 0 015 27 QM-IOOR - 7 58 18 I ref 48 50-50/B 750 747 10 0 007 674 HMX50, 8 74 21 7 1 48 g/cc 625 747 8 0 009 562 emulsion 1330 775 7 0008 60 fresh 500 733 II 0 006 347 un&conf 6 26 747 4 0013 27 unconf 375 727 10 0007 240 16Oglcc 6 32 721 4 0 012 25 ref 34 315 706 12 0006 170 ref 48 4 80 664 4 0011 17
25 0 7 06 9 0007 135 3 66 585 4 0010 12 190 687 9 0008 92 3 28 383 5 0005 9 160 668 9 0008 72 3 13 failed 125 651 7 0009 53 95 635 6 0010 38
QM-IOOR m 7 74 I8 I 50-50/E 62 5 7 62 9 0009 549 I 50 g/cc 500 747 I2 0006 335 60 days 375 726 13 0005 209 old 315 706 I4 0005 154 unconf 250 687 I3 0005 115 ref 34 190 668 11 0006 82
160 668 9 0007 69 125 605 10 0006 47 95 605 8 0008 35
I----- T-14
5
A 51 “1 1 tY A 8‘ CL re
‘able 2b, page 4 I :OMPOS,TES - NON-ALUMINIZED
Ro Us <XC> G RC” Ro Us <xe> G RC” ,matol - 6 71 I84 hmatol - 5 22 78 O/50 88 9 635 28 0002 515 0 123 471 58 0 004 59‘ nconf 63 5 628 22 0003 350 53 g/cc 635 648 15 0004 430
IP 1 63 5 630 22 0003 353 LN un- 63 5 626 23 0003 343 ieved, 635 623 24 0002 339 ast 50 8 646 12 0005 336 :f 30 50 8 601 25 0002 24,
50 8 643 14 0004 321 50 8 654 IO 0006 381 5” 8 600 25 OU02 235 50 8 622 I9 0003 272 38 1 627 14 0004 210 38 1 612 17 0003 187 38 I 595 20 0003 176 38 I 581 22 0003 165 38 I 602 18 0 003 179 25 2 554 17 0003 99 25 2 546 18 0003 96 25 2 541 19 0003 96 25 2 520 21 0002 91 25 2 522 20 0002 90 25 2 559 I7 0003 101 25 2 509 21 0002 88 25 2 560 17 0003 I01 1905 489 18 0003 65 1905 451 20 0002 61 I7 5 failed
,matol - 6 62 184 o/50 9950 637 25 0002 643 nconf 9950 637 25 0002 658 53 g/cc 889 632 25 ‘pe 2 79 0 628 24 N 600. 79 0 632 22 $0 km 63 5 630 I8 St 63 5 635 I7 f 30 510 625 16
51 0 624 17 44 5 614 I7 44 5 616 I6 38 I 607 16 38 1 609 16 315 5847 I7 315 5847 I7 252 5405 I8 25 2 5 19 20 252 5199 20 252 5207 20 25 2 5 195 20
0 002 0 002 0 003 0 003 0 004 0 004 0 004 0 003 0 004 0 004 0 004 0 003 0 003 0 003 0 002 0 002 0 002 0 002
543 467 488 388 406 295 289 235 240 189 196 142 142 97 94 94 94 94
1905 4765 IS 0 003 65 19 05 failed
17 failed
Og/cc 80 431 55 0004 311 ‘NT150. 636 418 48 0 005 24: 00 pm 636 427 45 0 005 25C LN 840. 636 430 44 0005 251 200 ,lm 497 415 38 0006 18, acked, nconf :f 30
49 7 49 7 44 I 44 I 44 I 37 7 37 7 37 7 31 5 31 5 31 5 25 2 25 2 25 2
I9 15 19 15 I2 65 12 65
403 41 0005 I,! 405 40 0 005 18: 388 39 0005 15‘ 391 39 0005 15‘ 400 37 0006 152 375 36 0006 12: 399 32 0007 l3( 397 32 0007 13: 382 29 0007 IOf 375 30 0007 IOf 386 28 0007 106 372 24 0008 82 3 89 22 0009 88 3 75 24 0008 85 379 18 0011 65 358 19 0010 62 295 I6 0010 37 305 15 0010 37 283 I2 0012 28 327 II 0016 29 273 I3 0011 27 268 13 0011 27 232 I2 0010 22 241 I2 0011 22 177 1, 0009 16 187 10 0009 I6 183 II 0009 I6
95 95 95 95
8 8
64 64 64 64 182 II 0009 16
6 25 failed matex m 7 00 177 1 50 8 694 5 0015 553 ,conr 254 684 4 0016 198 6 1 g/cc 127 653 5 0015 69 f 22 85 603 5 0012 37 ,mpB- c., 175 22 8 N 64 751 14 0 003 450 p-21 64 753 13 0003 461 59 g/cc 505 754 IO 0005 369 N 840. 505 751 II 0.004 355 !OO p’m 37 8 7 43 10 0005 239 lconf 378 757 7 0007 291 f 30 378 751 8 0006 266
254 755 5 0009 188 254 776 298 254 761 4 0012 212 254 749 6 0008 172 254 753 5 0009 I83 19 I 727 7 0007 106 191 736 6 0008 112
T-15
Table 2, page 5 I COMPOSITES: NON-ALUMINIZED & PBXN-III
Ro Us <xe> G Rcur 1 Ro Us <xe> G RCU Comp B- 19 I 728 7 0 007 106 PBXN- cs 5 95 20 5 AN I9 1 738 6 0 008 I,7 11, 5001 5637 15 0003 296 79-21 I9 I 721 I 0 006 102 Navy 2422 5 611 8 0005 137
124 705 5 0008 61 conf, 33 96 5 757 8 0006 233 124 705 5 0008 61 sizes(pm) 23 44 5 600 8 0005 133 124 700 6 0 007 60 RDX60 1894 5499 7 0006 99 124 713 5 0 009 64 AP 200 1266 5 123 7 0005 54 124 714 5 0 009 64 Al 5 I2 47 5 098 8 0005 53 12 4 714 5 0 009 64 179 1241 5 112 7 0005 53 8 55 687 4 0 010 39 g/cc 9 55 4 840 7 0005 37 8 55 678 5 0 009 38 ref 8 950 4855 7 0005 37 8 55 677 5 0009 38 7 94 failed 8 55 686 4 0 010 38 PBXN- cs 5 95 20 5 8 55 686 4 0010 38 111 4995 5632 I6 0003 289 6 85 670 4 0 010 30 Navy 3455 5540 I3 0003 187 6 85 670 4 0 010 30 unconf, 34 12 5 572 I2 0004 188 6 85 failed sizes(pm) 2495 5 315 12 0003 115
Prop- - 6 60 RDX 60 2485 5331 12 0003 117 ellant 9525 652 12 AP 200 2480 5365 I2 0004 120 B 9525 655 9 Al 5 2480 5421 II 0004 122 55.60 urn 95 25 6 44 I7 I 79 2478 5 365 I2 0004 119 AP 7620 644 14 g/cc 2406 5311 I2 0003 110 unconf 7620 644 14 ref 8 2401 5 309 12 go03 II0 ref 46 7620 644 14 2345 5383 II 0004 112
5080 642 IO 2225 5228 12 0003 99 5080 639 II 2055 519 11 0003 90 5080 64, 10 2052 5 158 12 0003 89 3175 627 9 2045 5 154 12 0003 89 3175 627 9 1934 5 036 12 0 003 80
Prop- cs 6 70 I7 75 failed ellant 7620 666 5 PBXN- ce 6 036 20 5 C 5080 647 12 Ill 49 95 5 688 16 0003 283 55-60 urn 3, 75 644 8 Australia 34 I3 5 527 I4 0003 I71 AP 2540 637 8 unconf 2406 5313 I3 0 003 108 unconf 1905 630 6 ref 9 2401 5312 13 0003 108 ref 46 2045 5 186 12 0003 87 Prop- - 7 07 PBXN- cc 6 036 20 5 ellant 5080 689 IO Ill 5000 5747 15 -iiE- 305 D 3175 683 7 Australia 23 49 5 513 IO 0004 117 55-60 wrn 31 75 680 8 conf 18945406 9 0004 89 AP 25 40 6 82 6 ref 9 1260 5 130 8 0005 52 unconf I9 05 665 6 Prop- - 6 40 ref 46 1905 668 6 ellant 9525 635 8
1588 654 6 A-l 9525 636 7 1588 656 6 55.6Omm 7620 631
prop- c0 7 31 AP 7620 628 12 ellant 5080 726 4 unconr 5080 628 8 I
IO I
E 3175 715 5 ref 46 5080 631 6 55-60 pm 25 40 719 4 31 75 609 9 AP 1905 708 4 3175 615 8 unconf 1588 710 3 3175 617 8 ref 46 1270 703 3 25 40 6 07 8
2540 605 8 25 40 6 07 8 1905 607 6 1905 605 6
T-16
:able 2, page 6 I :OMPOSITES: ALUMINIZED ; INORGANIC
Ro Us <xe> G Rcur 1 Ro Us <xe> G RCUI ‘rap- 1905 607 6 AP 4 95 5 :llant 1588 597 6 I 26 38 I 417 24 0 02 156 i-l 1588 593 6 a/cc 31 8 408 22 0 02 I25
ef 46 1270 611 5 155.60 b,,, 127 265 I6 003 37 1270 609 5 ref 46 12 7 265 16 003 37
‘rap- - 5 96 I2 7 265 I6 003 37 llant 5080 579 II 95% AP w 3 39 4
3175 567 9 5% Al 38 IO 320 12 0 05 221 5-60pm 3175 574 8 081 p/cc 25 40 312 10 0 06 I31 LP 25 40 5 63 8 unconf 1735 298 9 006 78 nconf 25 40 5 65 8 ref. 47 1270 283 8 007 5, :f 46 22 23 5 60 8 9 55 266 8 007 36
2223 555 8 AP-AI - 4 33 5 ‘rap- w 4 64 ref 47 3810 40, 15 0 03 200 llant 3175 380 22 Illg/cc 2540 392 12 0 04 122 ,-I 3175 388 21 unconf 1735 371 IO 005 73 5-6Omm 1270 265 I6 AP <IO 1270 355 9 005 50 iP 1270 265 16 Iw: Al 1270 349 9 005 48 onf 1270 265 16 <71*m 9 55 315 9 005 33 :f 46 AP-Al m 5 00 6 LN c.3 4 45 4 ref 47 3810 452 I8 -%?i- 182 0 2300 282 259 00022 708 125 E/CC 2540 434 14 0 03 110 /cc 230 0 nconf 202 0 oo- 202 0 20 FLm 178 5 :f 30 127 0
127 0 127 0 99 5 99 5
2 71 27, 00020 688 1735 40, 13 003 67 2 42 263 00018 587 2 30 274 00017 571 2 15 253 00017 491 I 89 193 00020 331 1 60 208 00015 331 161 207 0 0016 331 I 63 16, 00020 259 5080 4767 10 0 04 376 I 67 I60 00021 259 3265 4700 8 0 05 209
99 5 87 0 87 0 80 0 80 0 ,~ , ~ . . 0, 0 *alleo
AP - 239 25 061 g/cc 25 4 204 16 0 07 106 10,ml 12 7 169 12 007 42 ref 45 AP - 373 4 1 0 g/cc 1220 360 29 0 02 817 13krn 510 339 23 0 03 251 ref 44 175 278 15 004 61 AP - 374 4 I 0 dcc 38 I 343 16 0 04 189 IOr, 254 328 14 0 05 112 ref 45 175 305 12 005 68
127 282 II 005 45
T-17
Table 3 Data for cylinders where failure was measured
Homogeneous TNT, pressed TNT, pressed TNT, pressed TNT, pressed TNT, cast TNT, creamed TNT, liquid xtryl tetry, NM NT0 NT0 NT0 Heterogeneous XTX-8003 PBX-9404 NM-sil ica-guar X-0219 X-0290 PBX-9502 RDX 94 h/pew RDX 97 B/pew Camp B Cyclotol 77-23 PBXW-7 Composites ANFO, SW RX-HD I 34 56 4 55 40 HANFO 1 07 26 19 5 35 45 QM-100R X0-2016 1 41 28 8 42 7 20 38 QM-IOOR X0-20/8 1 45 28 8 47 7 20 34 QM-IOOR 70.3016 I 44 17 5 57 6 27 8 QM-IOOR 60-4018 I 46 11 55 7 60 12 QM-100R 60.40,6 1 47 I4 2 59 7 86 I2 QM-IOOR 60.4016 I 50 14 2 60 7 62 12 HMX 20, emulsion I 47 86 07 7 59 I8 HMX 30, emulsion 151 50 25 7 42 8 HMX 50, emukion I 60 32 38 8 74 4 Amatol 50/50 I 53 I8 3 45 6 71 I9 Amatol 50/50 1 53 183 47 6 62 19 Amatol 50/50 I 00 6 32 18 5 22 IO Amatex 20 I61 85 7 03 IO CompB-AN 79.21 I 59 6 85 67 7 75 4 PBXN-III, N, conf I 79 87 48 5 95 7 PBXN-I I I, N, unc I 79 185 50 5 95 12
Pa Rr detvel (mm&s) <&3 G @s-l RC”C WC) (mm) Ud D (mm) *Gpa-*) bw xf
0 80 3 75 I8 504 65 0040 23 37 I 00 4 25 34 5 23 45 0049 43 37 I 46 2 21 57 6 70 I4 0062 35 37 1 62 131 66 7 08 06 0084 29 37 I 62 7 25 66 7 I3 28 0018 153 37 I 62 73 6 94 27 I 44 1 42 6 57 3 27 0 94 3 92 20 5 86 8 0013 24 38 0 9s 2 38 48 5 85 2 011 34 38 I 03 1 36 6 I2 621 02 081 53 22 1 75 8 76 7 78 1 0039 26 25 1 85 85 79 8 23 2 0015 23 25 I 87 127 81 8 25 2 0016 46 24
1 53 0 I9 7 05 7 307 004 17 054 22 I 83 0 60 7 27 8 805 0 05 039 09 22 1 17 4 77 4 92 6550 4 0033 6 4 191 75 7 35 7 68 2 0017 20 22 I 90 45 7 71 13 27 I 89 3 88 7 42 7 78 IO 0031 10 26 1 56 25 60 850 28 0013 3 43 1 56 I 26 54 8 50 17 0018 12 43 I 71 2 14 67 7 92 13 0 023 3 23 1 74 30 76 8 21 1 0028 6 22 I 70 1 28 7 25 7 92 06 0073 3 43
1 I6 6 25 36 5 88 7 0019 6 IO.11 0 0020 0 0035 0 0018 0 0021 0 0096 0 0054 0 0053 0 0054 0 0005 0 0033 0 0065 0 0022 0 0023 0 0095
0 010 0 0052 0 0032
65 3’1 16 9 26 34 29 34 34 34 I3 34 17 34 19 34 3 48 3 48 2 48 19 30 21 30 4 30 2 27 II 30 12 8 28 8 49 22 Baratol 2 60 2, 5 46 4 90 8 0 051
AN 1 00 72 I 1 4 45 130 0002 37 30
T-18
Table 3, page 2
reference 50
90% RDX-talc
80% RDX-talc
75% RDX-talc
Pa Rf Radius smallest
(p/cc) (mm) at u, 4 f” ff fv+e I 10 35 40 5 05 0 40 0 IO 0 50 explosive grain I 25 45 50 5 10 0 35 0 20 0 55 size 100 pm 1 33 65 70 5 10 0 32 0 7.5 0 57
70% RDX-talc I 43 75 80 5 07 0 29 0 30 0 59
60% RDX-talc 1 66 85 90 5 90 0 20 0 40 0 60
55% RDX-talc I 80 33 33 0 15 0 45 0 60
50% RDX-talc 2 00 33 33 0 075 0 50 0 58
95% RDX-wax 1 05 45 50 53 0 39 0 05 0 44
90% RDX-wax 1 10 45 50 53 0 32 0 10 0 42
80% RDX-wax I 25 44 50 62 0 17 0 20 0 37
76% RDX-wax 1 32 44 50 67 0 094 0 24 0 33
72% RDX-wax I 39 44 50 73 0 012 0 28 0 29
70% HMX-talc 1 43 75 80 5 09 031 0 30 0 61
58% HMX-talc I 72 65 70 6 17 0 20 0 42 0 62
50% HMX-talc 2 05 38 6 30 0 038 0 50 0 54
90% HMX-wax 1 10 65 70 5 20 0 36 0 IO 0 46
58% HMX-wax 1 28 75 80 5 85 0 21 0 42 0 63
50% HMX-wax 1 42 85 90 6 80 0 00 0 50 0 50
90% TNT-talc I 10 75 80 4 IO 0 40 0 10 0 so
75% TNT-talc 1 33 85 90 4 10 0 28 0 25 0 53
70% TNT-talc 1 43 85 90 4 00 0 24 0 30 0 54
65% TNT-talc 1 54 95 10 0 4 45 0 20 0 35 0 55
60% TNT-talc I 66 65 70 4 55 0 15 0 40 0 55
55% TNT-talc 1 80 65 70 4 97 0 IO 0 45 0 55
90% TNT-AI I IO 75 80 4 10 0 40 0 10 0.50
65% TNT-AI 1 54 95 10 0 4 60 0 20 0 35 0 55
60% TNT-AI 1 66 65 70 0 15 0 40 0 55
55% TNT-AI I 80 65 70 5 39 0 IO 0 45 0 55
95% TNT- lucite pwd 1 05 II 120 4 07 0 36 0 05 041
85% TNT- Lucite pwd 1 16 16 5 18 0 4 88 0 26 0 15 041
80% TNT- kite pwd 1 25 11 12 0 4 80 0 19 0 20 0 39
78% TNT- lucite pwd 1 28 95 100 0 17 0 22 0 39
75% TNT- lucite pwd I 33 85 90 4 88 0 12 0 25 0 37
70% TNT- lucite pwd I 43 75 80 5 80 0 034 0 30 0 33
T-19
Table 3, page 3 reference 51
Liquid TNT, 85oC P. Rc containment
1 46 38 13 mm steel
Liquid TNT, 95aC
92% NM, acetone
90% NM, acetone
81 3% NM, acetone
60 glass 90 cellophane
1 45 36 I3 mm steel 48 glass 72 cellophane
1 IO 35 13 mln steel 27 glass 42 cellophane
1 09 46 2-12 mm steel 33 glass 54 cellophane
1 05 17 3-12 mm steel
AN
136 glass 220 cellophane
1 06 <3 5 mm steel >80 glass
>lOO cellophane
T-20
r
/
Table 4 Compositions of explosives used in this report
Explosive Composition of Mixtures (wt%) ABNBF 7-amine-4,6-dinitrobenzofuroxan
AN 80, TNT 20 AN 50, TNT 50 ammonium nitrate AN 94, fuel oil 6
Am&x 20 Amatol 50/50 AN ANFO-generic ANFO-NM ANFO-SW AP BX-4 c-4 COmF !. Comp B Cyclotol Cyclotol 77.23 DINGU DNBF DNT EDC-35 EDNA HANFO HMX ZO-emulsion HMX 30.emulsion HMX 40-emulsion HMX 50-emulsion IRX-1 IP.X-3A IRK-4 LX-04 LX-IO LX-17-l NM NM-silica NT0 Oct0l PBX-9404 PBX-9501 PBX-9502 PBXN-110 PBXN-111 PBXW-7 type II PBXW-123 PBXW-126 Pentolite Picric Acid Propellant A Propellant B
AN 77, water 16, mineral oil 6, emulsifier 1 AN 77, water 14 7, oil 3 9,sorbitol monooleate 0 7, ? ammonium perchlorate TATB 60, RDX 30, HMX, 5, Viton A 5 RDX 91, pib 9 RDX 91, wax 9 RDX 63, TNT 36, Wax 1 RDX 75, TNT 25 RDX 17, TNT 23 dinitroglycoiurile 4,6-dini~obenzofUroxan 2,4-dinitrotoluene TATB 95, k&F 5 (moist-aminated TATB) ethylenediamine nitramine AN 72 4, tixi oil 4 6, AN/water/emulsion 23 AN 57 2, HMX 20, SN 8 0, water 9 6, fuel oil 5 2 AN 50 1, HMX 30, SN 7 0, water 8 4, fuel oil 4 6 AN 42 9, HMX 40, SN 6 0, water 7 2, fuel oil 3 9 HMX 50, AN 35 8, SN 5 0, water 6 0, fuel oil 3 3 HMX 70, htpb 30 HMX 70, htpb 20, Al 10 HMX 30, htpb 30, AP 24, Al 16 HMX 85, Viton-A 15 HMX 90, Viton-A 10 TATB 92 5, k&F 7 5 (wet-aminated TATB) NM 94, nitroethane 4, nitropropane 1 NM 93, silica 6, guar gum I (gel) 5-nitro-1,2,4-hiazol-2-one HMX 75, TNT 25 HMX 94, nitroceliuiose-1 1 3, c e phosphate 3 HMX 95, estane 2 5, bdnpa 1 25, bdnpf 1 25 TATB 95, k&F 5 (dry-aminated TATB) HMX 88, htpb 12 RDX 20, AP 43, Al 25, htpb 12 TATB 60, RDX 35, Viton A 5 AP 44 8, Al 30 2, TMETN 18 8, pcl4 2, ndpa 1, ipdi 1 Al 26, NT0 22, AP 20, RDX 20, polyurethane 12 PETN 50, TNT 50 2,4,6-trinitrophenol plastisol-NC 55, AP 30, Al 15 plastisoi-NC 64 7, AP 35 3
T-21
Table 3, page 2
Explosive Composition of Mixtures (wt%) ProDellant c “l&sol-NC 64 7, AP 29 4, RDX 5 9 Pro;ella”t D $astisol-NC 64 7, Al’20 3, P.DX 15 Propellant E plastisol-NC 64 7, RDX 35 3 Propellant F plastisol-NC 54 7, KC1 30 4, AI 14 9 QM-100 AN 75, water 18, oil 5, glass microballoons 2 QM-lOOR, X0-20/6 AN 60 4, RDX 20, water 15 1, fuel oil 4 5 QM-IOOR, SO-2018 AN 59 3, RDX 20, water 14 8, fuel oil 5 9 QM-lOOR, 70-3016 AN 52 8, RDX 30, water 13 2, fuel oil 4 0 QM-lOOR, 60.4016 AN 45 3, RDX 40, water 11 3, f”el oil 3 4 QM-IOOR, 60-40/X AN 44 4, RDX 40, water 11 1, fuel oil 4 4 QM-IOOR, SO-SO/S AN 37 0, RDX 50, water 9 3, fuel oil 3 7 RDX-pew RDX variable, polyethylene wax variable 70% RDX-urethane RDX 70, polyurethane 29 65, graphite 0 35
72 RDX-urethane#3 72 RDX-urethane#S RX-OS-HD RX-52-AD RX-52.AE RX-54-AJ RX-HD T2 Tettyl Ult TATB X-0219 x-0290 x-0341 X-0342 x-0343 x-0344 XTX-8003 Binder htpb idpi n-100 ndpa PCl Pew pib “l&sol-NC bvf Abbreviations ANFO-NM ANFO-SW PBXN-111 -N PBXN-I 11-A
RDX 72, binder 28 C 33%,H 60,O 5 4,0 97 g/cc RDX 72, binder 28 C 14%,H 29, 0 29, Si 29, 1 02 g/cc HMX 74, TMETN 20, Tone 260 5 2 TATB 65, FEFO 31, pcl I 6, pvf 14, n-100 1 1 TATB 65, FEFO, 32, pcl, 1 6, pvf, 14 HMX 47, Al 28, TMETN 16, NC 8 AN 78 7, fuel oil 6 4, calcium nitrate 5 5, water 9 4 TATB 97, unknown binder 3 trinitro-2,4,6-phenylmethylnitramine ultratine-grain (6 bm) TATB TATB 90, K&F 10 TATB 95, K&F 5, became PBX-9502 TATB 90 25, HMX 4 75, k&F 5 TATB 85 5, HMX 9 5, k&F 5 TATB 80 75, HMX 14 25, k&F 5 TATB 71 25, HMX 23 75, k&F 5 PETN 80, silicone rubber (sylgard) 20 Composition hydroxy-terminated polybutadiene isophorone diisocyanate commerical isoceprate nitrodiphenylamine polycaprolacto”e polyethylene wax polyisobutylene nitrocellulose with about 10% nitrowlcerin polyvinylchloride
i?om New Mexico (Lee) from Sweden (Swedish Rock) from U S Navy (Forbes) from Australia (Kennedy)
_.
i