Abstract

The shape features and size distribution of fragments produced by metal shells under explosion loading have great significance for studies on weapons, industrial structures, and aircraft technology. However, it is unclear how best to describe the morphological characteristics and mass distribution of fragments, or whether a similar quantitative relationship exists between each fragment. Therefore, this paper reports the fragment characteristics and internal features of the fragmentation of metal shells under instantaneous explosion loading. An experiment was designed to measure the fragmentation and perforation of a steel cylinder shell filled with high explosives. Using fractal mathematical models, expressions for the volume and line fractal dimensions of the fragments are obtained. The volume fractal dimension, which is used to describe the mass or size distribution of the fragments, and the line fractal dimension, which is used to describe the projected contour of fragments or fragment perforations, were measured using a MATLAB mathematical model. The results reveal that the characteristic mass distribution and morphology of the fragments are statistically self-similar and can be characterized by the fractal dimension. The Gauss–Newton iterative method for the Rosin–Rammler distribution is superior to the existing fitting method, and the resulting volume and line fractal dimensions satisfy the relationship D3 + 2D1 = 5.

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