Analysis and Prediction of Hole Penetrated in Thin Plates under Hypervelocity Impacts of Cylindrical Projectiles

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-08-16 DOI:10.1007/s10338-023-00413-z

Na Feng, Mingrui Li, Kun Ma, Chunlin Chen, Lixin Yin, Gang Zhou, Chengwen Tan

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Abstract

The hole penetrated in thin metallic plates due to hypervelocity impacts of cylindrical projectiles was analyzed by experimental method. The projectile caused a hole-expanding effect when penetrating the target plate because of dynamic shear failure and extrusion. A new empirical model was presented to predict the perforation diameter in thin plates impacted by high-velocity cylindrical projectiles. The fitting coefficients resulted in a root-mean-square of 0.0641 and a correlation coefficient of 0.991. The errors between the predicted and the experimental values were less than 7.251%, and less than 4.705% for 93.333% cases of the dataset. The accuracy of the proposed model is much higher than that of Hill’s model. Compared with historical equations, the new model is more accurate and can well describe the variations of different parameters with the normalized penetrated hole. The model takes into account the strength of materials, which contributes to the excellent results. This paper could provide important theoretical support for the analysis of the perforation process and its mechanism.

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圆柱形弹丸超高速冲击下薄板穿孔的分析与预测

用实验方法分析了圆柱形弹丸超高速撞击金属薄板时穿透的孔洞。弹丸在穿透靶板时，由于动力剪切破坏和挤压，产生了扩孔效应。提出了一个新的经验模型来预测高速圆柱形弹丸冲击薄板的穿孔直径。拟合系数的均方根为0.0641，相关系数为0.991。预测值和实验值之间的误差小于7.251%，数据集93.333%的情况下的误差小于4.705%。该模型的精度远高于Hill模型。与历史方程相比，新模型更准确，能够很好地描述不同参数随归一化穿透孔的变化。该模型考虑了材料的强度，这有助于获得优异的结果。本文可为分析射孔过程及其机理提供重要的理论支持。

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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