Abstract
This study uses the unified strength theory to analyse the elastoplastic stage and plastic stage of a linear strain-hardening target material while considering the effects of the intermediate principal stress and the free lateral boundaries of the target. In this investigation, analytical solutions of the radial stress in the cavity wall are obtained, and a unified penetration model of the target material is built. On this basis, penetration resistance formulas and penetration depth formulas for rigid projectiles with various nose shapes penetrating into thick, finite-radius, metallic targets are deduced, the solutions of which are obtained by utilizing the Simpson method. Accordingly, the proposed method offers a broader scope of application and higher accuracy than previous methods. Through this method, a series of analytical solutions based on different criteria can be obtained, and the penetration depth ranges of targets under different striking velocities can be effectively predicted. Moreover, penetration processes under different conditions are numerically simulated using the software ANSYS/LS-DYNA to study the motion law of the projectiles and the dynamic response of the targets. From the theoretical and numerical approaches, a list of influencing factors for terminal ballistic effects are analysed, including the strength criterion differences, the strength parameter b, the striking velocity v 0 , the projectile nose shape, and the target radius-to-projectile radius ratio rt/a. The results indicate that, as b changes from 1 to 0, the penetration depth Dmax increases by 22.45%. Additionally, Dmax increases by 40.76% when rt/a changes from 16 to 4; hence, it cannot be calculated as an unlimited-size target anymore when rt/a ≤ 16. In weapons field tests, the radius of the metallic target can be conservatively designed to be greater than 28 times the projectile radius to ignore the effect from the free lateral boundaries of the target.
Highlights
Academic Editor: Zhixiong Li is study uses the unified strength theory to analyse the elastoplastic stage and plastic stage of a linear strain-hardening target material while considering the effects of the intermediate principal stress and the free lateral boundaries of the target
Penetration resistance formulas and penetration depth formulas are presented for rigid projectiles penetrating into thick, finite-radius, metallic targets. us, the model presented in this work, which is suitable for the penetration of rigid projectiles into semi-infinite metallic targets, has a broader scope of application and higher accuracy than previous models. rough simulations of the penetration process under different conditions with the finite element software ANSYS/LS-DYNA, the motion law of projectiles and the dynamic response of targets are studied. e analytical results in this paper are compared with the experimental and analytical results in relevant documents, which reveals that the solution in [14] is only a special case of the solution in this paper
A series of analytical solutions based on different strength criteria are obtained to effectively predict the penetration depth ranges of all kinds of targets with equal tensile and compressive strength under different striking velocities
Summary
Since the cylindrical cavity expansion model belongs to axisymmetrical plane strain problems, σz(σz m(σr + σθ)/2) is the intermediate main stress, where m is the rc rp rt re r. Combining equations (3a) and (3b) and (4a) and (4b), the relationship of effective stress-strain for linear hardening materials can be written as. Substituting (10) into (5a) and (5b), the relationship of effective stress-strain for linear hardening materials is given as σr −. R e momentum conservation equation of the target in the cylindrical coordinate system can be expressed as zσr + σr −. Equations (6), (7), and (9) and ((11a), (11b))∼(13) are the fundamental equations of the finite cylindrical cavity expansion model for incompressible linear hardening materials based on unified strength theory
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