高速弹丸撞击HY100钢的结晶相变化

Muna Y. Slewa
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摘要

高产量HY-100钢是一种独特的合金,以其在重型建筑中的应用而闻名。HY-100具有良好的延展性、缺口韧性、耐腐蚀性和可焊性。HY-100钢的物理特性和分子结构也是众所周知的;然而,高速弹丸撞击对该金属合金晶体结构和材料相的影响尚不清楚。实验研究了高速冲击对晶体结构和材料相变的影响。通过用Lexan弹丸撞击HY-100钢板(15.4 × 15.4 × 1.27 cm)来评估对晶体结构的影响结果。两级轻气炮在撞击点将这些弹丸加速到6.70公里/秒的速度。对冲击板表面进行了必要的制备,以便用电子背散射衍射(EBSD)显微镜进行检测。撞击后,对每个撞击板区域的10个区域进行了检查和分析。这些区域是从紧接在撞击坑下面的区域中选择出来的,直到没有受到撞击的物理影响的地方。采集的EBSD图像显示,主要相位为体心立方(BCC)。此外,还对面心立方相(FCC)和六边形紧堆积相(HCP)进行了索引。这些样品也在撞击后进行了分子结构分配变化的检查。然后根据与撞击坑相关的区域将结果制成表格。在本研究中,在撞击后所有阶段的一些地点都发现了HCP的痕迹。该研究还表明,BCC晶体结构在冲击后仍然是主要的相结构,并且对所有测试样品和所有水平的冲击载荷都是有效的。在这个速度下,由于冲击动量,损伤区在5微秒内形成。HY-100钢材料在高温和高准静压作用下发生可逆相变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Crystalline Phase Changes Due to High-Speed Projectiles Impact on HY100 Steel
High yield HY-100 steel is a unique alloy and well known for its employment in heavy construction. HY-100 offers good characteristics like ductility, notch toughness, corrosion resistance, and weldability. The physical characteristics and molecular structure of HY-100 steel are also well known; however, there is little known about the effect of high-velocity projectiles impact on this metal alloy’s crystalline structure and material phase. The effects of high-speed velocity impact on the crystalline structure and material phase changes are studied herein experimentally. The results of an impact on the crystalline structure are assessed by impacting HY-100 steel plates (15.4 × 15.4 × 1.27 cm) with Lexan projectiles. A two-stage light gas gun accelerates these projectiles to a velocity of 6.70 km/s at the point of the impact. The impacted plates’ surfaces are prepared as required for inspection by the Electron Back Scatter Diffraction (EBSD) microscope. Ten regions on each impacted plate area are examined and analyzed after impact. These regions are selected from the area immediately under the impact crater to locations that are not physically affected by the impact. Observations of collected EBSD images show that the predominant phase is Body-Centered Cubic (BCC). Moreover, Face-Centered Cubic (FCC) and Hexagonal-Close-Packed (HCP) phases are also indexed. The samples are also post-impact examined for molecular structure allocation changes. The results were then tabulated according to the regions relative to the impact crater. In this study, traces of HCP were found at some locations in all post-impact stages. This study also indicates that the BCC crystalline structure remained the dominant phase structure after impact, and it is valid with all test samples and all levels of shock loading. At this velocity, the damage zone develops within 5 microseconds due to impacting momentum. HY-100 steel materials go through a reversible phase change when subject to elevated temperature and high quasi-static pressure.
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