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Abstract: When spontaneous chaffs diffuse in air, numerous radiations are shielded, absorbed, and reflected between chaffs, and there is interaction between the chaffs and the air. This makes it relatively complicated to calculate radiation transmission. To calculate the spatial distribution and generate radiation images of spontaneous chaffs, a radiation calculation model based on reverse path sampling was constructed which takes account of the transmission characteristics of radiation. This model hypothesizes that all detectors transmit light outward uniformly in the opposite direction of the radiation. After sampling statistics of light routes, the number and intensity of lights received by detectors along the radiation path were calculated. Next, a spontaneous combustion model of chaff was constructed. In this model, the effects of the porous structure of the chaff surface on the combustion rate of reactive metals are considered. The accuracy of this model was proved by comparing calculated results with experimental data. Finally, the spatial distribution of chaff clouds was calculated and their radiation images obtained. The results from the constructed model proved to be highly accurate when compared with measurement data from an experimental rocket sled.

The establishment of the foil cloud combustion model is an important basis for the simulation study of the infrared radiation characteristics of the foil cloud. The paper establishes the combustion model of the foil cloud and carries out the infrared imaging experiment to verify the infrared radiation characteristics of the foil cloud emitted by the aircraft. It is very important.

高速气流作用下自燃箔片云团的辐射特性计算与实验研究

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