Numerical analysis of hot launch of missile from a launch canister
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摘要:
采用三维可压缩雷诺平均Navier⁃Stokes方程和
k⁃ε 湍流模型,研究了导弹出箱过程中,弹体姿态偏转后弹底周围环境及发射箱内的流场特性。首先,以超声速欠膨胀射流撞击平板实验为算例,对数值方法的有效性进行验证。其次,分别对导弹在约束期和半约束期箱内流动特性展开研究。研究表明:喷管尾流在发射箱内会形成强烈的引射效应。同时,在弹底会出现明显的回流区域,使导弹出箱时受到额外的阻力。考虑偏转后,发射装置受到的冲击载荷增大2倍以上,发射箱壁面受到的压力增加40%。而且,在半约束期,箱内的流场分布不再对称,会使得导弹受到额外的不平衡力矩。Abstract:Based on the three⁃dimensional compressible Reynolds⁃averaged Navier⁃Stokes equation and the
k ⁃ε turbulence model,the environment around the bottom of the missile and the flow field characteristics in the launch canister after deflection of the missile attitude were investigated.Firstly,the effectiveness of the numerical method was verified by the experiment of supersonic jet impinging on a flat plate.Secondly,the flow characteristics of the launch canister in the constrained and semi⁃confined periods were investigated respectively.The results showed that significant entrainment effect of the exhaust gas can be found in the launch canister.Meanwhile,a backflow area near the bottom of the missile can be observed,which may cause additional drag force on the missile during the launching process.After considering the deflection,the impact load on the launcher was increased by more than two times and the pressure on the launch box wall was increased by 40%.Moreover,the flow field distribution inside the box was no longer symmetrical during the semi⁃confinement period,making the missile subject to additional unbalanced moments.-
Key words:
- jet impingement /
- non simultaneous derailment /
- launch canister /
- ejection effect /
- secondary flow
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图 5 Grid a~Grid d沿喷嘴轴线上的压力分布
Figure 5. Pressure distributions along the nozzle axis of the Grid a~Grid d
图 6 实验结果与本文计算结果流场对比图
Figure 6. Flow field comparison between experimental results and calculation results
图 8 在对称平面和Z=2.0D,Z=6.3D处马赫数分布
Figure 8. Mach number distribution in the symmetry plane and Z=2.0D,Z=6.3D
图 9 全约束期对称平面上速度矢量
Figure 9. Velocity vector in the symmetry plane during full constraint period
图 11 对称平面和
2.0D, 6.3D横截面上的马赫数分布 Figure 11. Mach number distribution in the symmetry plane and
2.0D, 6.3D cross section 
图 12 发射箱上表面温度分布
Figure 12. Temperature distribution on the upper surface of the launch canister
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