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The Detonation Properties of Combined Effects Explosives

Published online by Cambridge University Press:  10 January 2012

Paul Anderson
Affiliation:
Explosives Research and Development Branch, US Army ARDEC, Picatinny Arsenal, NJ 07806 USA
Paula Cook
Affiliation:
Explosives Research and Development Branch, US Army ARDEC, Picatinny Arsenal, NJ 07806 USA
Wendy Balas-Hummers
Affiliation:
Explosives Research and Development Branch, US Army ARDEC, Picatinny Arsenal, NJ 07806 USA
Andy Davis
Affiliation:
Nammo Talley, Research and Development, Mesa, AZ, 85277 USA
Kyle Mychajlonka
Affiliation:
Nammo Talley, Research and Development, Mesa, AZ, 85277 USA
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Abstract

In development of new explosives, it is often necessary to balance a number of attributes in performance while certain formulation constraints exist. Statistical design of experiments (DOE) is a valuable tool for rapid formulation optimization and minimization of costly and hazardous testing. During the development of metal-loaded explosives designed for enhanced blast, it was discovered that upon proper formulation, aluminum additives obtained full reaction by 7 volume expansions, which resulted in extremely high Gurney energies equivalent to LX-14 and PBXN-5 but with lower loading of nitramines. The early aluminum oxidation can be described by Eigenvalue type detonations, where the fully reacted Hugoniot of the condensed phase aluminum oxide and explosive products lies below the unreacted aluminum Hugoniot. Such an analysis describes fully the agreement of aluminum consumption by 7 volume expansions from 1-inch copper cylinder expansion tests and an analytic cylinder model, as well as detonation calorimetry. With the early reaction of aluminum also comes a shift in the gaseous reaction products to higher enthalpy species such as CO and H2, leading to further augmentation of blast. Thus, both the mechanical energy (for fragmentation or “metal pushing”) and blast (for structural targets) are available in a single explosive fill. This provides capability for combined metal pushing and blast in a single explosive that was not previously possible. Development of such explosives and the importance of modern statistical design of experiments will be shared.

Type
Research Article
Copyright
Copyright © Materials Research Society 2012

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References

REFERENCES

[1] Anderson, P., Balas, W., Pincay, J., Baker, E., Capellos, C.. Development, Optimization and Application of Combined Effects Explosives. Proceedings of the 2009 NDIA IM/EM Technology Symposium. May 1114, 2009, Tucson, AZ.Google Scholar
[2] Volk, F., Schedlbauer, F.. Products of Al Containing Explosives Detonated in Argon and Underwater. Proceedings of the 10th International Detonation Symposium, July 1216, 1993, Boston, MA.Google Scholar
[3] Gilev, S.D., Anisichikin, V.F.. Interaction of Aluminum with Detonation Products. Combustion, Explosion, and Shock Waves, Vol. 42, 107115, 2006.Google Scholar
[4] Trzcinski, W.A., et al. . Studies of Free Field and Confined Explosions of Aluminum Enriched RDX Compositions. Propellants, Explosives, Pyrotechnics, Vol. 32, 502508, 2007.Google Scholar
[5] Makov, M.N., et al. . Acceleration Ability and Heat of Explosive Decomposition of Aluminized Explosives. Combustion, Explosion, and Shock Waves, Vol. 40, 458466, 2004.Google Scholar
[6] Makov, M.N.. The Heat and Products of Explosion of Aluminized High Explosives. Proceedings of the 31st International Annual Conference of ICT. Energetic Materials: Analysis, Diagnostics and Testing, July 36, 2001, Karisruhe, Germany.Google Scholar
[7] Davis, A.R., et al. . Anaerobic Detonation Behavior of Selected Enhanced Blast and Combined Effects Explosives. Proceedings of the JANNAF 43rd Combustion Subcommittee Meeting, December 711, 2009, La Jolla, CA.Google Scholar
[8] Carney, J.R., Lightstone, J.M., McGrath, T.P. II, Lee, R.J.. Fuel-Rich Explosive Energy Release: Oxidizer Concentration Dependence. Propellants, Explosives, Pyrotechnics, Vol. 34, 331339, 2009.Google Scholar