Explosive fragmentation of brittle granular materials

IF 4.7 2区工程技术 Q1 MECHANICS

Engineering Fracture Mechanics Pub Date : 2025-04-06 DOI:10.1016/j.engfracmech.2025.111126

Chuanshan Zhang , Chun Feng , Jun Zhou , Kun Xue

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Abstract

This study experimentally investigates the dynamic fragmentation behaviors of brittle granular materials subjected to explosive loadings, employing a concentric shell configuration. The setup consisted of a high-explosive sphere surrounded by a densely packed shell of dry glass spheres. To minimize reflection enhancement, the particle shells were confined within thin-walled glass casings, effectively simulating air-exposed conditions. This configuration allowed rarefaction waves reflected from the outer surface of the particle shell to significantly influence particle fragmentation, particularly in thinner shells. A specialized fragment-collecting apparatus was designed to prevent collision-induced damage to particle fragments, enabling the recovery of most fragments with preserved post-test morphologies following the explosion tests. A comprehensive analysis was conducted on the breakage extent and pulverization degree of the fragmented brittle particles, utilizing metrics such as breakage index, fragmentation volume fraction, and fractal dimension. These parameters exhibited significant variations as the particle shell thickness increased from a dimension comparable to the explosive radius to several times that radius. Notably, the thinnest particle shell underwent near-total particle crushing, evidenced by a fractal dimension of up to 3.2, indicating intense fractal crushing. When the shell thickness increased to 3.75 times the explosive radius, the fragmentation volume fraction was nearly halved, and the fractal dimension decreased significantly. These variations in fragmentation behaviors highlight the impact of divergent blast waves, which impart transient explosive loadings with rapidly decaying overpressures on the particles. The experimental results elucidate the relationship between explosive fragmentation and transient explosive loadings, providing estimations for the radii of pulverized and fractured spherical zones. Particles fragmented by explosive loadings exhibit a markedly higher fractal dimension compared to those fractured by quasi-static loadings, even when fragmentation volume fractions are similar. This suggests distinct breakage mechanisms between the two loading conditions.

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本研究采用同心壳配置，对脆性颗粒材料在爆炸载荷作用下的动态破碎行为进行了实验研究。实验装置包括一个高爆球体，其周围是密密麻麻的干玻璃球壳。为了尽量减少反射增强，颗粒外壳被限制在薄壁玻璃壳内，有效模拟了暴露在空气中的条件。这种构造使得从粒子外壳外表面反射的稀释波能够显著影响粒子的破碎，特别是在较薄的外壳中。设计了专门的碎片收集装置，以防止碰撞引起的颗粒碎片损坏，从而使大多数碎片在爆炸试验后都能以保留的试验后形态进行回收。利用断裂指数、碎裂体积分数和分形维度等指标，对碎裂脆性颗粒的断裂范围和粉碎程度进行了综合分析。当颗粒外壳厚度从与爆炸半径相当的尺寸增加到爆炸半径的几倍时，这些参数会出现明显变化。值得注意的是，最薄的颗粒外壳几乎完全破碎，分形维度高达 3.2，表明分形破碎非常严重。当外壳厚度增加到爆炸半径的 3.75 倍时，碎裂体积分数减少了近一半，分形维数也显著下降。碎裂行为的这些变化凸显了发散爆炸波的影响，这种爆炸波会给颗粒带来快速衰减超压的瞬态爆炸载荷。实验结果阐明了爆炸破碎与瞬态爆炸载荷之间的关系，提供了对粉碎和断裂球形区域半径的估计。与准静态载荷相比，即使碎裂体积分数相似，爆炸载荷碎裂的颗粒也表现出明显更高的分形维度。这表明两种加载条件下的断裂机制截然不同。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Engineering Fracture Mechanics 物理-力学

CiteScore

8.70

自引率

13.00%

发文量

606

审稿时长

74 days

期刊介绍： EFM covers a broad range of topics in fracture mechanics to be of interest and use to both researchers and practitioners. Contributions are welcome which address the fracture behavior of conventional engineering material systems as well as newly emerging material systems. Contributions on developments in the areas of mechanics and materials science strongly related to fracture mechanics are also welcome. Papers on fatigue are welcome if they treat the fatigue process using the methods of fracture mechanics.