THE INVESTIGATION OF THE SUBSURFACE LAYER TREATMENT IN COURSE OF THE CARBON-CARBON COMPOSITE LIQUID-PHASE IMPREGNATION

The saturation treatment of the two-dimension reinforced carbon-carbon composite materials (CCCM) was investigated in the article. The goal was to study the impregnation of the porous CCCM by such substances as MoSi2 and TaSi2. The liquid-phase treatment was used, the Si and Mo plates were placed above the CCCM's surface and the temperature was elevated up to 1500 °C. The resulting structure of the samples was studied, the depth of the impregnated layer was defined and the phase analyses allowed to determine the elements distribution in the impregnated layer. Ill. 8. Ref. 12. Tab. 2.

1. Dong, J. Improved mechanical properties of carbonreinforced epoxy composites by growing carbon black on carbon fiber surface / J. Dong, C. Jia, M. Wang [et al.] // Compos. Sci. Technol. ― 2017. ― Vol. 6. ― P. 350‒363.

2. Jina, X. Advances in oxidation and ablation resistance of high and ultra-high temperature ceramics modified or coated carbon/carbon composites / X. Jina, X. Fana, C. Lu [et al.] // J. Europ. Ceram. Soc. ― 2016. ― Vol. 56. ― P. 24‒32.

3. Wang, S. Oxidation mechanism of SiC-zirconia-glass ceramic сoated carbon/carbon сomposites at 1123‒1273 K / S. Wang, F. Zeng, Y. Li [et al.] // Mater. Res. Bull. ― 2017. ― Vol. 5. ― P. 25‒31.

4. Jinn, H. Effects of oxygen partial pressure on the oxidation of ZrB2‒SiC–graphite composites at 1800 °C / H. Jinn, S. Meng, X. Zhang [et al.] // Ceram. Int. ― 2016. ― Vol. 4. ― P. 6480‒6486.

5. Shu, F. Structure and high-temperature property of amorphous composite coating synthesized by laser cladding FeCrCoNiSiB high-entropy alloy powder / F. Shu, S. Liu, H. Y. Zhao [et al.] // J. Alloys Compd. ― 2017. ― Vol. 15. ― P. 84‒93.

6. Fu, G. Y. A high-silicon anti-oxidation coating for carbon steel at high temperature / G. Y. Fu, L. Q. Wei, X. M. Zhang [et al.] // Surf. Coat. Technol. ― 2016. ― Vol. 12. ― P. 15‒25.

7. Sua, F. Creep behavior of C/SiC composite in hot oxidizing atmosphere and its mechanism / F. Sua, P. Huanga, J. Wub [et al.] // Ceram. Int. ― 2016. ― Vol. 11. ― P. 56‒63.

8. Dai, J. In-situ growth of SiC nanostructures and their influence on anti-oxidation capability of C/SiC composites / J. Dai, J. Sha, J. i Shao [et al.] // Fire safety. ― 2017. ― Vol. 25. ― P. 78‒80.

9. Li, T. Dynamic compressive fracture of C/SiC composites at different temperatures: microstructure and mechanism / T. Li, Y. Duan, K. Jin [et al.] // International Journal of Impact Engineering. ― 2017. ― Vol. 63. ― P. 45‒51.

10. Fan, X. Bond stability and oxidation resistance of BSAS-based coating on C/SiC composites / X. Fan, W. Huang, H. Liu [et al.] // Surf. Coat. Technol. ― 2017. ― Vol. 309. ― P. 35‒46.

11. Dua, B. Oxidative protection of a carbon-bonded carbon fiber composite with double-layer coating of MoSi2‒SiC whisker and TaSi2‒MoSi2‒SiC whisker by slurry method / B. Dua, C. Honga, Q. Qu [et al.] // Ceram. Int. ― 2016. ― Vol. 70. ― P. 52‒65.

12. Eremin, S. Parameters of chemical vapor deposition on a structure and the properties of nanostructured TaC coating on a carbon composite material / S. Eremin, V. Anikin, I. Burmistrov [et al.] // Nanomechanics Science and Technology: An International Journal. ― 2014. ― Vol. 5, № 3. ― P. 181‒189.