期刊文献+

On the study of ricochet and penetration in sand,water and gelatin by spheres,7.62 mm APM2,and 25 mm projectiles 被引量:7

On the study of ricochet and penetration in sand, water and gelatin by spheres, 7.62 mm APM2, and 25 mm projectiles
下载PDF
导出
摘要 We examine the ricochet and penetration behavior in sand, water and gelatin by steel spheres, 7.62 mm APM2 and 25 mm projectiles. A threshold impact angle(critical angle) exists beyond which ricochet cannot occur. The Autodyn simulation code with the smooth particle hydrodynamic(SPH) method and Impetus Afea Solver with the corpuscular model are used and the results are compared with experimental and analytical results. The resistance force in sand for spheres was proportional to a term quadratic in velocity plus a term linear in velocity. The drag coefficient for the quadratic term was 0.65. The Autodyn and Impetus Afea codes simulate too large penetration due to the lack of a linear velocity resistance force. Critical ricochet angles were consistent with analytical results in the literature. In ballistic gelatin at velocities of 50–850 m/s a drag coefficient of 0.30 fits the high speed camera recordings if a linear velocity resistance term is included. However, only a quadratic velocity resistance force with drag coefficient that varies with the Reynolds number also fits the measurements. The simulation of a sphere in water with Autodyn showed too large drag coefficient. The 7.62 mm APM2 core simulations in sand fit reasonable well for both codes. The 25 mm projectile ricochet simulations in sand show consistency with the high speed camera recordings. Computer time was reduced by one to two orders of magnitudes when applying the Impetus Afea Solver compared to Autodyn code due to the use of the graphics processing units(GPU). We examine the ricochet and penetration behavior in sand, water and gelatin by steel spheres, 7.62 mm APM2 and 25 mm projectiles. A threshold impact angle(critical angle) exists beyond which ricochet cannot occur. The Autodyn simulation code with the smooth particle hydrodynamic(SPH) method and Impetus Afea Solver with the corpuscular model are used and the results are compared with experimental and analytical results. The resistance force in sand for spheres was proportional to a term quadratic in velocity plus a term linear in velocity. The drag coefficient for the quadratic term was 0.65. The Autodyn and Impetus Afea codes simulate too large penetration due to the lack of a linear velocity resistance force. Critical ricochet angles were consistent with analytical results in the literature. In ballistic gelatin at velocities of 50–850 m/s a drag coefficient of 0.30 fits the high speed camera recordings if a linear velocity resistance term is included. However, only a quadratic velocity resistance force with drag coefficient that varies with the Reynolds number also fits the measurements. The simulation of a sphere in water with Autodyn showed too large drag coefficient. The 7.62 mm APM2 core simulations in sand fit reasonable well for both codes. The 25 mm projectile ricochet simulations in sand show consistency with the high speed camera recordings. Computer time was reduced by one to two orders of magnitudes when applying the Impetus Afea Solver compared to Autodyn code due to the use of the graphics processing units(GPU).
出处 《Defence Technology(防务技术)》 SCIE EI CAS CSCD 2016年第2期159-170,共12页 Defence Technology
关键词 明胶微球 渗透行为 炮弹 光滑粒子流体动力学 阻力系数 模拟显示 高速摄像机 Ricochet Simulation Sand Gelatin Autodyn Impetus Afea Solver Smooth particle Sphere
  • 相关文献

参考文献53

  • 1Pierazzo E, Melosh HJ. Understanding oblique impacts from experiments,observations, and modeling. Annu Rev Earth Planet Sci 2000;28:141–7.
  • 2Braslau DJ. J Geophys Res 1970;75:3987–99.
  • 3Nakata Y, Hyodo M, Hyde AFL. Microscopic particle crushing of sandsubjected to high pressure one-dimensional compression. Soils Found2001;41:69–82.
  • 4Parab ND, Claus B, Hudspeth MC, Black JT, Mondal A, Sun J, et al.experimental assessment of fracture of individual sand particles atdifferent loading rates. Int J Impact Eng 2014;8:14.
  • 5Omidvar M, Iskander M, Bless S. Response of granular media to rapidpenetration. Int J Impact Eng 2014;66:60–82.
  • 6Robins B. New principles of gunnery. Richmond, Surrey: RichmondPublishing Co. Ltd; 1972.
  • 7Euler L. Neue grunds-tze der artillerie. Berlin: Von B.G. Teubner; 1922.
  • 8Poncelet JV. Cours de Mécanique Industrielle. 1829.
  • 9Resal H. Sur la penetration d’un projectile dans les semifluids it lessolides, cr. 120:397–401. 1895.
  • 10Forrestal MJ, Luk VK. Penetration into soil targets. Int J Impact Eng1992;12:427-4.

同被引文献68

引证文献7

二级引证文献31

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部