Numerical Simulation of Fragmentation Process Driven by Explosion in Elliptical Cross-Section Warhead
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摘要: 为研究爆轰驱动下椭圆截面自然破片杀伤战斗部壳体的膨胀破裂过程以及壳体破片径向速度分布,建立了椭圆截面战斗部三维模型。通过AUTODYN-3D软件,采用Lagrange算法模拟爆轰驱动下椭圆截面自然破片战斗部壳体的膨胀断裂过程,研究了端面单点中心起爆方式下短长轴断裂时间差与短长轴比的关系,以及不同起爆点、不同短长轴比和不同装填比(即装药与壳体质量之比)对椭圆截面战斗部径向破片速度分布的影响。结果表明:与端面中心单点起爆、端面长轴双点偏心起爆和端面短长轴四点偏心起爆相比,端面短轴双点偏心起爆方式对椭圆截面战斗部壳体破片径向速度的增益效果最好。装填比一定时,短、长轴断裂时间以及短、长轴断裂时间差与短长轴比呈线性关系,战斗部壳体膨胀过程中截面形状的实时短长轴比与加载时间呈线性关系;随着短长轴比的增大,战斗部壳体破片径向速度增益逐渐减小。短长轴比一定,装填比小于1时,破片速度随方位角增大呈正弦趋势上升,且短、长轴方向破片速度差与装填比呈线性关系。Abstract: In order to study the expand-rupturing process and the radial velocity distribution of the elliptical cross-section natural fragment warhead shell driven by detonation, a three-dimensional model of the elliptical cross-section warhead was established. The AUTODYN-3D software was used to simulate the expansion and rupture process of the elliptical cross-section natural fragment warhead shell driven by detonation with Lagrange algorithm. The relationship between the minor-major axis fracture time difference and the minor-major axis ratio under the single-point central initiation mode of the end face was studied. The influence of initiation points, minor-major axis ratio and loading ratio (i.e. the mass ratio of charge and shell) on the radial velocity distribution of the elliptical cross-section warhead was studied. The results show that compared with the single-point initiation at the center of the end face, the double-point eccentric initiation at the major axis of the end face and the four-point eccentric initiation at the minor axis of the end face, the double-point eccentric initiation at the minor axis of the end face has the best effect on the radial velocity gain of the elliptical cross-section warhead shell. When the loading ratio is constant, the fracture time of the minor and major axes and the difference between the fracture time of the minor and major axes are linearly related to the minor and major axis ratio. Meanwhile, the real-time minor and major axis ratio of the cross-section shape during the expansion of the warhead shell varies linearly with loading time. The radial velocity distribution of warhead shell fragments decreases with the increase of minor-major axis ratio. When the ratio of minor axis to major axis is constant and the loading ratio is less than 1, the fragment velocity increases sinusoidally with the increase of azimuth angle, and the difference of fragment velocity in minor and major axes shows a linear relationship with the loading ratio.
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图 6 战斗部中部平面内爆轰波的传播
Figure 6. Detonation wave propagation in the middle section of warhead
图 7 椭圆截面战斗部壳体膨胀断裂过程
Figure 7. Expansion fracture process of elliptical cross-section warhead shell
图 8 战斗部中部壳体的破片速度
Figure 8. Velocity of shell fragment in the middle section of warhead
图 10 不同初始短长轴比战斗部截面形状随时间变化曲线
Figure 10. Cross-sectional shape versus time curves of warheads with different
$\,\mu $ 0
图 11 战斗部短、长轴方向壳体的断裂时间
Figure 11. Fracture time of warhead shell in the direction of minor and major axes
图 13 起爆方式对破片径向速度分布的影响
Figure 13. Influence of initiation mode on radial velocity distribution of fragments
图 14
$\,\mu $ 0对破片径向速度分布的影响Figure 14. Influence of
$\,\mu $ 0 on radial velocity distribution of fragments
图 15
$\,\mu $ 0对短长轴方向破片速度差值的影响Figure 15. Influence of
$\,\mu $ 0 on the velocity difference of fragments in the major and minor axes
图 16
$\,\beta $ 对壳体破片径向速度分布的影响Figure 16. Influence of
$\,\beta $ on radial velocity distribution of shell fragments
图 17
$\,\beta $ 对短长轴方向破片速度差的影响Figure 17. Influence of
$\,\beta $ on the velocity difference of fragments in the minor and major axesMaterial $\,\rho $/(g·cm−3) A/MPa B/MPa n C Melting point/K D60 7.83 831 1280 0.672 0.027 1811 
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表 2 数值模拟中采用的材料模型
Table 2. Material models of numerical simulation
Component $\,\rho $/(g·cm−3) Equation of state Constitutive equation Failure D60 shell 7.83 Liner Johnson-Cook Principal strain 2A12 cover board 2.75 Shock Johnson-Cook Plastic strain 8701 explosive 1.71 JWL
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表 3 试验与数值模拟结果对比
Table 3. Comparison of experimental and numerical simulation results
Mass range/g n1 n2 [0.10, 0.20) 228 281 [0.20, 0.25) 126 103 [0.25, 0.30) 30 33
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表 4 不同短长轴比椭圆截面战斗部模型参数
Table 4. Model parameters of elliptical cross-section warhead with different
$\,\mu $ 0Test No. x/mm y/mm Thickness of shell/mm $\,\beta $ $\,\mu $0 1 30.62 12.25 2.35 0.633 0.4 2 27.39 13.69 2.44 0.633 0.5 3 25.00 15.00 2.50 0.633 0.6 4 23.15 16.20 2.54 0.633 0.7 5 21.65 17.32 2.56 0.633 0.8 6 20.41 18.37 2.57 0.633 0.9 7 19.36 19.36 2.57 0.633 1.0
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表 5 不同装药与壳体质量比的椭圆截面战斗部模型参数
Table 5. Model parameters of elliptical cross-section warhead with different mass ratios of charge to shell
Test No. x/mm y/mm Shell thickness/mm $\,\mu $0 $\,\beta $ 1 25 15 3.66 0.6 0.49 2 25 15 3.06 0.6 0.59 3 25 15 2.46 0.6 0.75 4 25 15 2.16 0.6 0.86 5 25 15 1.86 0.6 1.00 6 25 15 1.56 0.6 1.20
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