截卵形弹体侵彻加筋板架结构数值仿真

Numerical simulation on truncated oval-nosed projectile penetrating into stiffened plate

  • 摘要:
      目的  基于数值仿真,对弹速范围内加筋板架结构的抗侵彻性能、吸能模式及不同加筋类型对弹体飞行姿态的影响进行研究。
      方法  应用有限元软件LS-DYNA对截卵形弹体侵彻加筋板架结构的过程进行数值仿真,并将数值仿真结果与实验结果进行对比,验证数值仿真方法的可靠性。改变弹体的初始速度,分别运用动量法、等效质量法对弹体剩余速度进行预报,比较不同方法在各速度段的适用性,提取加筋板架结构不同区域的变形能,从而分析弹体初速度对加筋板架结构吸能模式的影响。最后改变加强筋的结构,分析着弹点与筋相对位置关系对弹体侵彻姿态的影响。
      结果  研究表明,当弹体初速度在300~900 m/s范围内时,对于弹体侵彻加筋板架结构的剩余速度预报,等效质量法相较于动量法准确性更高,加筋板架结构的变形能所占弹体损失能量的比例随弹体初速度的增加而减小,T形筋加筋板架结构对弹道的影响程度大于矩形筋加筋板架结构。
      结论  相关计算方法及研究结果对加筋板架结构的抗侵彻研究及工程应用具有一定参考价值。

     

    Abstract:
      Objectives  In this paper, the numerical simulation method is used to study the anti-penetration performance and energy absorption mode of a stiffened plate, as well as the influence of different stiffened bars on the flight attitude of the projectile body.
      Methods   Finite element software LS-DYNA is used to simulate the process of a truncated oval-nosed projectile penetrating a stiffened plate, and the results of the numerical simulation are compared with an experiment to verify the reliability of the numerical simulation method. The momentum method and mass equivalence method are used to predict the residual velocity of the projectile, and the applicability of different theoretical methods within different velocity ranges is compared. The deformation energy of different regions of the stiffened plate is then extracted to analyze the influence of the initial velocity of the projectile body on the energy absorption mode of the target plate. Finally, the structure of the stiffeners is changed and the influence of the relative position of the stiffeners on the penetration attitude of the projectile body is analyzed.
      Results  The results show that the mass equivalence method is more accurate than the momentum method in predicting the residual velocity of the stiffened plate when the initial velocity of the projectile body is in the range of 300–900 m/s. The ratio of the deformation energy of the stiffened plate to the energy loss of the projectile body decreases with the increase of the initial velocity of the projectile body. The effect of a T-stiffened plate on trajectory is greater than that of a rectangular-stiffened plate.
      Conclusions  The related calculation method and research results have certain reference value for research and engineering application surrounding the anti-penetration of stiffened plates.

     

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