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Abstract
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A wide range of applications in the field of munitions require assessment of the potential blast impulse to structures arising from the nearby detonation of a cased explosive charge. The gases liberated following detonation of the charge are obliged to share energy and momentum with the casing. The blast impulse is thereby reduced. However, where a casing fractures, before it can be accelerated to near to its final velocity, gases under significant remaining pressure can escape and the blast impulse is not reduced to the same degree.
Researchers in the fields of explosives safety or effects often need to estimate the impulse delivered by blast escaping from the fragmenting casings of exploding munitions, relative to the blast impulse from the same explosive charge uncased. Even for free-field conditions, researchers currently depend for such estimates on formulae which either are not soundly derived (e.g. that of Fisher), or are simply fits to available experimental data. This paper will show that a sound analytical formula can be derived, using as a basis the physical assumptions of R.W. Gurney, which are already the basis for other well-known and useful approximations in this field. Furthermore, this new formula can be extended in application to the common situation where the casing fragments before it reaches a high radius of expansion, thus allowing more blast impulse to escape. Drawing on recent work by A.B. Crowley, this can be achieved by including a dependency on the ratio of casing yield stress and explosive product gases internal pressure. An extended set of formulae incorporating this sensitivity to explosive and casing properties are shown to be consistent, at least qualitatively, with recent experimental data from researchers at BAE Systems. |