Tensile creep properties and damage mechanisms of 2D‐woven C/HfC–SiC composites in high temperature

To achieve the repeatability of aerospace thermal components, C/TaC‒SiC composites were fabricated. Cycle ablation and bending tests were carried out. After 3 × 60 s of ablation beyond 2100°C, the mechanical property retention rate was 80.9%. Interestingly, a reaction similar to “ouroboros ring,” in which the cyclic reactions of “TaC being oxidized to Ta2O5 and Ta2O5 being reduced to TaC,” occurred in the central ablation region of C/TaC‒SiC composites. On the one hand, the continuous generation of TaC could prevent liquid state Ta2O5 from being blown off central ablation region, playing a similar role in “water and soil conservation.” On the other hand, liquid Ta2O5 covered the surface of C/TaC‒SiC composites during ablation process, contributing to block the inward permeation of oxidized gases. In addition, novel “Grotto” structures were detected in the transitional ablation region of C/TaC‒SiC composites. The formation reason of the “Grotto” structure has also been discussed.

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Tensile creep properties and damage mechanisms of 2D‐woven C/HfC–SiC composites in high temperature

Cited by 2 publications

References 35 publications

Microstructure and ablation resistance of C/C-HfC-SiC composites prepared by RMI with different powder particle sizes

Microstructure and ablation resistance of C/C-HfC-SiC composites prepared by RMI with different powder particle sizes

Self‐defending mechanism of C/TaC‒SiC composites under 2100°C cyclic ablation environment

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