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刻槽弹体旋转侵彻铝靶试验与数值模拟
引用本文:庞春旭,何勇,沈晓军,张先锋,郭磊. 刻槽弹体旋转侵彻铝靶试验与数值模拟[J]. 弹道学报, 2015, 27(1)
作者姓名:庞春旭  何勇  沈晓军  张先锋  郭磊
作者单位:南京理工大学 智能弹药技术国防重点学科实验室,南京 210094
摘    要:为研究刻槽弹体旋转侵彻作用性能,分析了刻槽弹体旋转侵彻作用过程,在着靶速度400~700 m/s范围对刻槽弹体和卵形弹体旋转侵彻铝靶进行了试验研究,利用LS-DYNA动力学软件对刻槽弹体和卵形弹体旋转侵彻过程进行了数值仿真,仿真和试验结果吻合较好,表明仿真方法及材料模型的适用性。进行了着靶速度300~700 m/s,转速0~1 500 r/s条件下的仿真试验。仿真结果表明,旋转对刻槽弹体侵深具有很大的影响,在弹体转速和着靶速度达到合理匹配时,旋转的刻槽弹体可以有效地提高弹体的侵深。

关 键 词:侵彻力学  旋转  刻槽弹体

Experimental Investigation and Numerical Simulation on Grooved Projectile Rotationally Penetrating Into Aluminum Target
PANG Chun-xu,HE Yong,SHEN Xiao-jun,ZHANG Xian-feng,GUO Lei. Experimental Investigation and Numerical Simulation on Grooved Projectile Rotationally Penetrating Into Aluminum Target[J]. Journal of Ballistics, 2015, 27(1)
Authors:PANG Chun-xu  HE Yong  SHEN Xiao-jun  ZHANG Xian-feng  GUO Lei
Affiliation:Ministerial Key Laboratory of ZNDY,NUST,Nanjing 210094,China
Abstract:To study the rotary penetration effect of grooved projectile,the rotary penetration process of grooved projectile was analyzed,and the experiments of ogive-nosed and grooved projectiles rotationally penetrating into aluminum targets at the impact velocity from 400 m/s to 700 m/s were carried out.The rotary penetration processes of grooved projectile and ogival projectile were numerically simulated by LS-DYNA finite element code.The simulation results agree well with experiment results,and the simulation method is applicable for predicting the results of rotary penetration.Further simulations were conducted at the impact velocity from 300m/s to 700 m/s and rotation velocity in the range of 0—1 500 r/s.Results show that rotation has a significant effect on the penetration depth of grooved projectile.While the rotation and impact velocity of the projectile match reasonably,the rotary grooved projectile can improve the penetration depth effectively.
Keywords:penetration mechanics  rotation  grooved projectile
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