Fracture behavior and mechanism of highly fragmented steel cylindrical shell under explosive loading

IF 5 Q1 ENGINEERING, MULTIDISCIPLINARY
Kang Wang , Peng Chen , Xingyun Sun , Yufeng Liu , Jiayu Meng , Xiaoyuan Li , Xiongwei Zheng , Chuan Xiao
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引用次数: 0

Abstract

An in-depth understanding of the fracture behavior and mechanism of metallic shells under internal explosive loading can help develop material designs for warheads and regulate the quantity and mass distribution of the fragments formed. This study investigated the fragmentation performance of a new high-carbon silicon-manganese (HCSiMn) steel cylindrical shell through fragment recovery experiments. Compared with the conventional 45Cr steel shell, the number of small mass fragments produced by the HCSiMn steel shell was significantly increased with a scale parameter of 0.57 g fitted by the Weibull distribution model. The fragmentation process of the HCSiMn shell exhibited more brittle tensile fracture characteristics, with the microcrack damage zone on the outer surface being the direct cause of its high fragmentation. On the one hand, the doping of alloy elements resulted in grain refinement by forming metallographic structure of tempered sorbite, so that microscopic intergranular fracture reduces the characteristic mass of the fragments; on the other hand, the distribution of alloy carbides can exert a "pinning" effect on the substrate grains, causing more initial cracks to form and propagate along the brittle carbides, further improving the shell fragmentation. Although the killing power radius for light armored vehicles was slightly reduced by about 6%, the dense killing radius of HCSiMn steel projectile against personnel can be significantly increased by about 26% based on theoretical assessment. These results provided an experimental basis for high fragmentation warhead design, and to some extent, revealed the correlation mechanism between metallographic structure and shell fragmentation.

爆炸荷载下高度破碎钢制圆柱形外壳的断裂行为和机理
深入了解金属弹壳在内部炸药加载下的断裂行为和机理,有助于开发弹头材料设计,并调节碎片的数量和质量分布。本研究通过碎片回收实验研究了一种新型高碳硅锰(HCSiMn)钢圆柱形弹壳的破片性能。与传统的 45Cr 钢壳相比,HCSiMn 钢壳产生的小质量碎片数量显著增加,其尺度参数为 0.57 g,由 Weibull 分布模型拟合。HCSiMn 钢壳的破碎过程表现出更多的脆性拉伸断裂特征,外表面的微裂纹破坏区是其高破碎率的直接原因。一方面,合金元素的掺杂通过形成回火索氏体的金相组织而导致晶粒细化,从而使微观晶间断裂降低了碎片的特征质量;另一方面,合金碳化物的分布可对基体晶粒产生 "销钉 "效应,使更多的初始裂纹形成并沿着脆性碳化物扩展,进一步提高了壳体的破碎率。虽然对轻型装甲车辆的杀伤力半径略微减小了约 6%,但根据理论评估,HCSiMn 钢弹丸对人员的密集杀伤半径可显著增加约 26%。这些结果为高破片弹头的设计提供了实验依据,并在一定程度上揭示了金相结构与炮弹破片之间的相关机理。
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来源期刊
Defence Technology(防务技术)
Defence Technology(防务技术) Mechanical Engineering, Control and Systems Engineering, Industrial and Manufacturing Engineering
CiteScore
8.70
自引率
0.00%
发文量
728
审稿时长
25 days
期刊介绍: Defence Technology, a peer reviewed journal, is published monthly and aims to become the best international academic exchange platform for the research related to defence technology. It publishes original research papers having direct bearing on defence, with a balanced coverage on analytical, experimental, numerical simulation and applied investigations. It covers various disciplines of science, technology and engineering.
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