气压变化影响扩展源释能的实验及仿真研究

doi:10.16182/j.issn1004731x.joss.25-1109

摘要/Abstract

摘要：

为探明低气压环境下扩展源的能量释放特性，通过实验与仿真结合的方法开展了研究。选择4组典型高度对应气压作为实验工况，采用红外热像仪对扩展源燃烧过程的燃烧温度、辐射亮度、燃烧面积等参数进行监测。气压从101 kPa降至30 kPa时，扩展源的起燃时间延长1倍，总能量释放衰减44.78%，燃烧面积减小45.95%，但峰值温度与平均温度波动小于3%，表明扩展源通过调整红外尺度而非辐射亮度来维持热力学平衡。基于传热传质控制方程与多孔介质扩散理论建立仿真模型，计算结果与实验数据的最大误差低于13.07%，验证了仿真模型在宽气压变动范围内结果预测的可靠性。研究结果解释了扩展源燃烧系统在不同气压状态下的能量释放特性及相应参数的变化规律，为典型环境下扩展源使用及设计优化提供支撑。

关键词: 扩展源燃烧, 低压气实验, 多孔介质, 传热传质, 扩散系数

Abstract:

To investigate the energy release characteristics of extended sources in low-pressure environments, a combined experiment and simulation approach was adopted. Four typical altitude-corresponding pressures were selected as experimental conditions. An infrared thermal imager was employed to monitor parameters such as combustion temperature, radiance, and combustion area during the combustion process of the extended source. When the pressure decreases from 101 kPa to 30 kPa, the ignition time of the extended source doubles; the total energy release attenuates by 44.78%, and the combustion area reduces by 45.95%, but the fluctuations of peak temperature and average temperature are less than 3%, which indicates that the extended source maintains thermodynamic equilibrium by adjusting the infrared scale rather than the radiance. A simulation model was established based on heat and mass transfer governing equations and porous medium diffusion theory. The maximum error between the calculated results and experimental data is less than 13.07%, which verifies the reliability of the simulation model in predicting results within a wide range of pressure variation. The research results explain the energy release characteristics and variation laws of corresponding parameters of the extended source combustion system under different pressure states, providing support for the application and design optimization of extended sources in typical environments.

Key words: extended source combustion, low-pressure experiment, porous medium, heat and mass transfer, diffusion coefficient

中图分类号:

TN972+.4

过凯,赵非玉,张昊等 . 气压变化影响扩展源释能的实验及仿真研究[J]. 系统仿真学报, 2026, 38(6): 1761-1770.

Guo Kai,Zhao Feiyu,Zhang Hao,et al . Experimental and Simulation Study on Energy Release of Extended Sources Influenced by Atmospheric Pressure Variation[J]. Journal of System Simulation, 2026, 38(6): 1761-1770.

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工况标号	飞行高度/m	对应气压/kPa
I	0	101.33
II	3 000	70.11
III	6 000	47.18
IV	9 000	30.44

压力/kPa	起燃时间/s	达标时间/s
101	1.00	10.02
70	1.50	8.07
47	2.63	4.93
30	2.37	3.03

参数	数值
扩展源孔隙直径/cm	1.29×10^-6
扩展源长度/cm	4.9
扩展源宽度/cm	2.31
扩展源厚度/cm	5×10^-3
速率常数/(cm/s)	3×10^-2
扩展源有效面积(cm²/g)	2.2×10⁵
扩展源密度/(g/cm³)	1.97
化学反应生成热/(J/mol)	572 240
扩展源发射率	0.8
扩展源比热容/(J/(g·K))	0.45
扩展源速度/(cm/s)	30
空气导热系数/(W/(cm·K))	2.51×10^-4
空气动力粘度/(g/(cm·s))	1.81×10^-4
理想气体常数/((g·cm²)/(s²·mol·K))	8.314×10⁷

压力/kPa	实验/(W·sr^-1)	仿真/(W·sr^-1)	相对误差/%
101	1.000 0	0.966 2	3.38
70	0.936 0	0.866 8	7.39
47	0.817 0	0.710 2	13.07
30	0.449 6	0.502 2	11.70