Defence Technology (Apr 2016)

Simulating geometrically complex blast scenarios

  • Ian G. Cullis,
  • Nikos Nikiforakis,
  • Peter Frankl,
  • Philip Blakely,
  • Paul Bennett,
  • Paul Greenwood

DOI
https://doi.org/10.1016/j.dt.2016.01.005
Journal volume & issue
Vol. 12, no. 2
pp. 135 – 147

Abstract

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The effects of blast waves generated by energetic and non-energetic sources are of continuing interest to the ballistics research community. Modern conflicts are increasingly characterised by asymmetric urban warfare, with improvised explosive devices (IEDs) often playing a dominant role on the one hand and an armed forces requirement for minimal collateral effects from their weapons on the other. These problems are characterised by disparate length- and time-scales and may also be governed by complex physics. There is thus an increasing need to be able to rapidly assess and accurately predict the effects of energetic blast in topologically complex scenarios. To this end, this paper presents a new QinetiQ-developed advanced computational package called EAGLE-Blast, which is capable of accurately resolving the generation, propagation and interaction of blast waves around geometrically complex shapes such as vehicles and buildings. After a brief description of the numerical methodology, various blast scenario simulations are described and the results compared with experimental data to demonstrate the validation of the scheme and its ability to describe these complex scenarios accurately and efficiently. The paper concludes with a brief discussion on the use of the code in supporting the development of algorithms for fast running engineering models.

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