Definition of scaled distance of close-in explosion and blast load calculation model
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摘要: 如何准确界定“近距离爆炸(close-in explosion)”一直是防护工程研究领域的热点。本文中基于已被充分验证的精细化有限元模型,研究了TNT球形装药自由场爆炸冲击波传播与爆轰产物高速膨胀共同作用的特点和规律,发现在比例爆距小于0.80 m/kg1/3的范围内,爆轰产物对刚性壁面的爆炸荷载影响显著,提出球形装药近距离爆炸的比例爆距界定标准为0.30~0.80 m/kg1/3。研究发现,在近距离爆炸下,爆炸波在入射角为0°~5°范围内的刚性壁面反射荷载峰值会出现急剧下降的现象,这是由爆轰产物喷射的不均匀性和随机性导致的;近距离爆炸下,刚性壁面反射超压出现了两个峰值的现象,这是由冲击波和爆轰产物分别与刚性壁面相互作用导致的。提出了近距离爆炸情况下两个荷载峰值的计算公式,以及适合工程结构响应计算的简化荷载模型;揭示了近距离爆炸下刚性壁面反射超压的分布规律。Abstract: How to accurately define “close-in explosion” has always been a hotspot in the field of protection engineering research. In this paper, based on the fully validated 2D axisymmetric fine finite element model, the characteristics and laws of the propagation of air shock waves and high-speed expansion of detonation products generated by TNT spherical charge were studied. It is found that there is a significant influence of the detonation products on the blast load on rigid wall when the range of the scaled distance less than 0.8 m/kg1/3. It is recommended to use the scaled distance range from 0.30 m/kg1/3 to 0.80 m/kg1/3 as the definition criterion of close-in explosion for spherical TNT charge explosion. It was found that: due to the inhomogeneity and randomness of the detonation product rapid expansion, the peak value of the rigid-wall reflected overpressure experienced a sharp drop within a range of incident angle of 0°~5° in the case of close-in explosion defined in the paper. In addition, there were two peaks on the reflected overpressure curve in close-in explosion cases, and the first peak overpressure was caused by the interaction between the shock wave and rigid wall while the second peak overpressure was generated by the interaction between the detonation products and rigid wall. Based on curve fitting, the formulas for calculating the two peak values were proposed, respectively, and a simplified load model suitable for calculation of engineering structure response was put forward; The distribution law of the reflected overpressure on the rigid wall under close-in explosion was revealed.
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Key words:
- detonation products /
- scaled distance /
- close-in explosion /
- load calculation model
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图 3 不同网格尺寸情况下超压峰值与比例爆距的关系
Figure 3. Peak overpressure versus scaled distances with different mesh sizes
图 4 自由场超压峰值与比例爆距的关系
Figure 4. Incident free-field overpressures versus scaled distances
图 7 5种比例爆距工况的刚体反射超压曲线
Figure 7. Reflected overpressure curves at five types of scale distances
图 8 0.50 m/kg1/3比例爆距工况下冲击波反射与爆轰产物撞击作用现象
Figure 8. Reflection of blast wave and detonation product at 0.50 m/kg1/3
图 9 冲击波与爆轰产物到达时间及荷载峰值
Figure 9. Scaled arrival times and peak pressures of shock wave and detonation products
图 11 不同比例爆距工况下刚性壁面荷载峰值分布
Figure 11. Load distributions at different types of scale distances
图 12 冲击波正反射超压峰值拟合曲线(0.30 m/kg1/3<Z≤0.80 m/kg1/3)
Figure 12. Fitting curve of peak normal reflected overpressures of shock waves (0.3 m/kg1/3<Z≤0.8 m/kg1/3)
图 13 冲击波到达比时间拟合曲线(0.30 m/kg1/3<Z≤0.80 m/kg1/3)
Figure 13. Fitting curve of scaled arrival times of shock waves (0.30 m/kg1/3<Z≤0.80 m/kg1/3)
图 14 爆轰产物荷载峰值拟合曲线(0.30 m/kg1/3<Z≤0.80 m/kg1/3)
Figure 14. Fitting curve of peak overpressures of detonation products (0.30 m/kg1/3<Z≤0.80 m/kg1/3)
图 15 爆轰产物到达比时间拟合曲线(0.30 m/kg1/3<Z≤0.80 m/kg1/3)
Figure 15. Fitting curve of scaled arrival times of detonation products (0.30 m/kg1/3<Z≤0.80 m/kg1/3)
图 16 比冲量结果曲线(0.30 m/kg1/3<Z≤0.80 m/kg1/3)
Figure 16. Scaled impulses fitting curves for 0.30 m/kg1/3<Z≤0.80 m/kg1/3
密度/(kg·m−3) 爆速/(m·s−1) pCJ/GPa A/GPa B/GPa w R1 R2 E/(MJ·m−3) 1630 6930 21 371.2 3.231 0.3 4.15 0.95 7000 
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表 2 空气模型参数
Table 2. Parameters for modeling air
密度/(kg·m−3) C0 C1 C2 C3 C4 C5 C6 E/(MJ·m−3) 1.2929 0 0 0 0 0.4 0.4 0 0.25
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