Dynamic modeling and experimental study to predict the thermal-reactive flow characteristics of infrared decoy flares under sub-atmospheric pressure

Infrared decoy flares are regarded as an optimal cost-effective countermeasure for aircraft protection in the aerospace and military fields. The coupling effects of sub-atmospheric pressure and complex airflow under high-altitude flight conditions substantially modulate the energy release characteristics of the pyrotechnic payload. The unsteady thermal-reactive flow characteristics of Mg/Teflon/Viton (MTV) pyrotechnics under negative-pressure environments are examined in this study through an integrated experimental and numerical approach. Sub-atmospheric pressure conditions representative of various cruise altitudes are replicated employing a vacuum combustion chamber. The thermal radiation processes of the pyrotechnic compositions under varying pressures are synchronously captured by high-speed camera and high-frequency infrared thermography, while quantitative temperature profiles are acquired via an infrared thermometer. A three-dimensional transient flow-reaction coupling solution model, simulating dynamic flight conditions, is established. Afterburning effects are computed based on a modified reaction mechanism comprising 17 species and 18-step elementary reactions. Notably, high fidelity of the numerical model is demonstrated through multi-index validation against experimental data. The results indicate that the combustion duration, infrared radiance, and flame temperature exhibit significant pressure dependency. Within the negative-pressure conditions, the reaction rate-controlling process is dominated by chemical kinetics, while the inhibitory effect exerted by the negative-pressure environment on the oxidation reaction of Mg is markedly more pronounced than that observed for the fluorination reaction. This research provides deeper insight into the dynamic combustion processes of aerospace pyrotechnics and offers crucial support for advancing the evaluation techniques concerning infrared decoy flares interference efficacy in practical countermeasure scenarios.