Abstract
Carbon/carbon composites are usually used as a thermal protection material in the nose cap and leading edge of hypersonic vehicles. In order to predict the thermal and ablation response of a carbon/carbon model in a hypersonic aerothermal environment, a multiphysical coupling model is established taking into account thermochemical nonequilibrium of a flow field, heat transfer, and ablation of a material. A mesh movement algorithm is implemented to track the ablation recession. The flow field distribution and ablation recession are studied. The results show that the fluid-thermal-ablation coupling model can effectively predict the thermal and ablation response of the material. The temperature and heat flux in the stationary region of the carbon/carbon model change significantly with time. As time goes on, the wall temperature increases and the heat flux decreases. The ablation in the stagnation area is more serious than in the lateral area. The shape of the material changes, and the radius of the leading edge increases after ablation. The fluid-thermal-ablation coupling model can be used to provide reference for the design of a thermal protection system.
Highlights
With the development of hypersonic technology, the requirements of thermal protection materials are becoming higher and higher [1, 2]
Carbon/carbon composites are widely used in the thermal protection system of aircraft because of their high latent heat and good strength at high temperature [3]
A fluid-thermal-ablation coupling model of carbon/carbon composites in a hypersonic environment is established considering the thermochemical nonequilibrium of a flow field, heat transfer, and ablation of material
Summary
With the development of hypersonic technology, the requirements of thermal protection materials are becoming higher and higher [1, 2]. The flow field around the aircraft affects the heat transfer and ablation of carbon/carbon composites, changing the thickness and shape of the thermal protection layer. It is important to establish a fluid-thermalablation coupling model and predict the temperature distribution and ablation response of carbon/carbon composites. Martin and Boyd established a coupling model between flow and a thermal protection material, mainly analysed the temperature response of a thermal protection material in a hypersonic environment, and validated the numerical method with IRV-2 [6]. The existing studies for the response of a thermal protection material usually predict the material response by one-way coupling, without considering the effects of material temperature and ablation shape change on the external flow field. A fluid-thermal-ablation coupling model of carbon/carbon composites in a hypersonic environment is established considering the thermochemical nonequilibrium of a flow field, heat transfer, and ablation of material. The temperature distribution, ablation recession, and shape change of the carbon/carbon model at different times are analysed
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