An experimental study on the explosion process of high-temperature molten tin liquid contacted with water
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摘要: 为研究低熔点金属锡遇水爆炸机理及能量转化过程,搭建了一套由高频熔融炉、高速摄像机和信号采集仪等组成的可视化实验平台,监测锡与水的质量比为5、10、15和20时熔融锡液与水接触反应过程,并选取中高熔点金属铝进行相同条件下的对比实验。同时,结合能量守恒定律、爆炸冲击理论建立数学计算模型,用于定量分析爆炸冲击波能量。结果表明:质量比为5时,熔融锡液与水反应触发2次蒸汽爆炸;由相同条件下熔融铝液遇水爆炸实验,反应剧烈程度和持续时间与金属碎化程度和金属热扩散率有关。此外,高温熔融锡液遇水爆炸过程中,0.45%~10.91%热能转化为冲击波能量。随着质量比的增加,冲击波能量转化率呈现先增后减趋势;当质量比为10时,冲击波能量转化率最大。由锡/铝遇水爆炸实验的冲击波压力曲线可知,当质量比小于12.69时,锡液遇水爆炸实验的冲击波能量转化率高于铝液遇水爆炸实验的冲击波能量转化率。Abstract: To study the explosion mechanism and the energy conversion process of the interaction between low melting point metal tin and water, a visual experiment platform is built to monitor the contact reaction processes at different mass ratios of tin to water, e.g., 5, 10, 15 and 20. The platform consists of a high-frequency melting furnace, a high-speed camera, signal collectors and other equipment. Meanwhile, high melting point metal aluminum is selected for comparative experiments under the same experimental conditions to explore the differences in reaction characteristics between low melting point metal tin and high melting point metal aluminum during the steam explosion. Some mathematical calculation models are established to quantitatively analyze the shock wave energy in line with the law of conservation and explosive shock theory. The results show that two steam explosions are triggered when molten tin reacted with water at a mass ratio 5; and in the comparative explosion experiments of molten tin with water and molten aluminum with water under the same experimental conditions, the reaction intensity and the duration during the explosion of molten metal with water are respectively related to the degree of fragmentation and thermal diffusivity. In addition, the calculation indicates that about 0.45% to 10.91% of the heat energy stored in the molten tin is converted into the explosion shock wave energy throughout the steam explosions. Moreover, the shock wave energy conversion ratio is affected by the mass ratio; and this effect is reflected in that the energy conversion ratio of the shock wave first increases and then decreases with the increase in mass ratio; when the mass ratio is 10, the energy conversion ratio is the largest. It is also found in comparison experiments that the shock wave energy conversion ratios in the explosion experiments of tin reacting with water are higher than the shock wave energy conversion ratios in the explosion experiments of aluminum reacting with water when the mass ratio is less than 12.69.
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图 2 高温熔融锡液遇水的反应过程
Figure 2. Reaction process of high-temperature molten tin liquid contacted with water
图 3 高温熔融锡液遇水的压力曲线
Figure 3. Pressure curve of high-temperature molten tin liquid contacted with water
图 4 高温熔融铝液遇水的反应过程
Figure 4. Reaction process of high-temperature molten aluminum liquid contacted with water
图 5 不同质量比时高温熔融锡液遇水的冲击波能量转化率
Figure 5. Shock wave energy conversion ratios of high-temperature molten tin liquid contacted with water at different mass ratios
图 6 高温熔融锡/铝液遇水的平均冲击波能量转化率
Figure 6. Mean shock wave energy conversion ratios of high-temperaturemolten tin/aluminum liquid contacted with water
表 1 高温熔融锡液遇水的实验数据
Table 1. Experimental data of high-temperature molten tin liquid contacted with water
mr/kg mw/kg n Qr/kJ ∆p/MPa w/kg η/% 0.7031 0.140 5 199.36 0.22 0.0031 6.51 0.7224 0.144 204.84 0.24 0.0035 7.15 0.7490 0.150 212.38 0.25 0.0037 7.29 1.1230 0.225 318.43 0.28 0.0043 5.65 0.5944 0.059 10 168.54 0.27 0.0041 10.18 0.6108 0.061 173.19 0.29 0.0045 10.87 0.6355 0.063 180.20 0.30 0.0047 10.91 0.6452 0.065 182.95 0.30 0.0047 10.75 1.98 0.132 15 467.50 0.156 0.00348 3.11 2.01 0.134 473.67 0.272 0.00728 6.43 2.18 0.145 508.63 0.119 0.00237 1.95 2.26 0.151 525.08 0.242 0.00625 4.98 1.86 0.093 20 442.82 0.043 0.00048 0.45 2.00 0.100 471.61 0.072 0.00112 0.99 2.21 0.111 514.80 0.068 0.00102 0.83 2.28 0.114 529.20 0.065 0.00095 0.75 
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