前分形障碍物爆破缓减的数值模拟

IF 2.1 Q2 ENGINEERING, CIVIL
Omar Ghareeb Alshammari, Obed Samuelraj Isaac, S. Clarke, S. Rigby
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引用次数: 0

摘要

利用高保真CFD求解器对基于Sierpinski地毯的预分形障碍物相互作用引起的下游冲击波衰减机理进行了数值研究。在三种不同的尺度距离(Z = 1.87、2.24、2.99 m/kg1/3)下,对四次预分形迭代的爆炸缓解效果进行了定性和定量评估。在与下游区域破坏性波浪干涉图案的位置有关的区域,可以看到缓解现象。关键是,随着预分形迭代的增加,这些区域在空间上变宽,并且在孤立块状障碍物的下游区域通常会遇到强烈的冲击-冲击相互作用,导致负载放大,而在更分形的障碍物中则没有观察到。从波阻抗的角度探讨了衰减的机理。研究发现,预分形减少了波在下游的传播,增加了爆炸波的反射,并增强了在预分形障碍范围内的捕获,极大地改变了传播波的方向性,从而改变了传播波的强度。最高迭代预分形(即最接近真实分形的障碍物)的峰值压力降低了60%,峰值比冲降低了40%,从而突出了这种形状用于改善爆炸缓解的防护结构设计的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical modelling of blast mitigation of pre-fractal obstacles
The mechanics of downstream blast wave attenuation caused by interaction with obstacles arranged into a pre-fractal shape based on the Sierpinski carpet was numerically investigated using a high-fidelity CFD solver. The blast mitigation was qualitatively and quantitatively assessed for four pre-fractal iterations at three different scaled distances ( Z = 1.87, 2.24, 2.99 m/kg1/3). Mitigation was seen to occur in zones associated with the location of destructive wave interference patterns in the downstream region. Crucially, these zones were found to widen spatially with increasing pre-fractal iteration, and strong shock-shock interactions that result in load amplification, commonly encountered in downstream regions of a solitary block-like obstacle, were not observed for the more fractal-like obstacles. The mechanisms of attenuation are explored in terms of wave impedance. It is found that pre-fractals reduce wave transmission in the downstream, increase reflection of the blast wave, and enhance trapping within the confines of the pre-fractal obstacle, dramatically changing the directionality and hence the strength of the transmitted wave. Reductions in peak pressure of up to 60% and peak specific impulse of up to 40% were recorded for the highest iteration pre-fractal, that is, obstacles that most closely represent a true fractal, thereby highlighting the effectiveness of such shapes for protective structure design for improved blast mitigation.
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来源期刊
CiteScore
4.30
自引率
25.00%
发文量
48
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