Multi-fragmentation of various metals under dynamic radial expansion

When a cased explosive charge detonates, its metallic envelop inflates because of the expansion of the detonation products until its multiple fragmentation that generates high kinetic energy debris. In industrial and military applications, the spatial distribution of the fragments and their statisti...

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Bibliographic Details
Main Authors: Seisson, Gabriel, Gant, Fanny, Longère, Patrice, Maï, Skander El, Zinszner, Jean-Luc
Format: Conference Proceeding
Language:English
Subjects:
Detonation
Energy distribution
Fragmentation
Fragments
Hemispheres
Kinetic energy
Military applications
Spatial distribution
Stability analysis
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Summary:When a cased explosive charge detonates, its metallic envelop inflates because of the expansion of the detonation products until its multiple fragmentation that generates high kinetic energy debris. In industrial and military applications, the spatial distribution of the fragments and their statistics in terms of number, mass, and velocity are mandatory to assess safety or lethality areas. Since the founding works of N.F. Mott (1940’s), numerous experimental, theoretical and numerical studies have been issued on the fragmentation of cased charges or simplified configurations such as hemispheres, cones, cylinders or rings. The present authors recently contributed to this topic designing the PIDRET set-up (plate-impact-driven ring expansion test) that is able to expand reliably thin metallic rings at strain rates close to 104 s−1. This work provides new in-situ and post-mortem observations of ring expansion for various metals. Number of fragments and visible necks are compared to existing analytical approaches such as linear stability analysis (LSA) and Grady’s model.
ISSN:0094-243X
1551-7616
DOI:10.1063/12.0028601