Development of Cf/C-UHTC composite and study of its resistance to oxidation and ablation in high-speed high-enthalpy air plasma flow

Q1 Engineering

International Journal of Lightweight Materials and Manufacture Pub Date : 2024-02-06 DOI:10.1016/j.ijlmm.2024.02.003

A.N. Astapov , V.A. Pogodin , I.V. Sukmanov , B.E. Zhestkov , M.V. Prokofiev

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Abstract

This article contains the results of research on the development of a C_f/C-UHTC carbon fabric composite based on a viscose precursor and a combined matrix consisting of partially sintered ceramics in a system consisting of HfC–HfB₂–NbC–NbB₂–TiC–TiB₂–B₄C–SiC, amorphous carbon, and pyrocarbon. The SiC fraction does not exceed 8.5–9.0 wt%. In its initial state, the composite has open porosity, with apparent and true densities of 18–22%, 2.25–2.29 g/cm³ and 2.79–2.91 g/cm³, respectively. The bending strength and the elasticity modulus are 27.8 ± 0.7 MPa and 7.8 ± 0.2 GPa, respectively, and the fracture strain is 0.85 ± 0.05%. The tests for resistance to oxidation and ablation were carried out in a gas dynamic flow regime and non-equilibrium air plasma heating at flow rates of 4.5–4.8 km/s and breaking enthalpy of 45–50 MJ/kg. Heating was performed in the temperature range T_w = 1400–2700 °C at the critical point on the front surface of the samples. The average linear ablation rate and mass loss rate of the composite are 6.3 ± 0.3 μm/s and 6.22 ± 0.44 mg/s. The estimated value of the conductivity factor is 0.280–0.285 W/(m K). The performance ability of the composite arises from the formation and evolution of a passivating heterogeneous oxide film consisting mainly of titanium niobate Ti₂Nb₁₀O₂₉, mixed solutions of Hf₁₋_xTi_xO₂, (Ti₁₋_xHf_x)₁₋_yNb_yO_z and (Ti₁₋_xHf_x)NbO₄ with broad homogeneity ranges, and also encapsulated carbide and boride particles. It is shown that the oxidation resistance of the composite increases as a result of the transition through a number of phases into a liquid state as the working temperature increases.

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开发 Cf/C-UHTC 复合材料并研究其在高速高焓空气等离子体流中的抗氧化性和抗烧蚀性

本文介绍了一种 Cf/C-UHTC 碳纤维复合材料的研究成果，该复合材料基于粘胶前体和由 HfC-HfB2-NbC-NbB2-TiC-TiB2-B4C-SiC 体系中的部分烧结陶瓷、无定形碳和热碳组成的组合基体。其中 SiC 的含量不超过 8.5-9.0 wt%。在初始状态下，复合材料具有开放的孔隙率，表观密度和真实密度分别为 18-22%、2.25-2.29 g/cm3 和 2.79-2.91g/cm3。弯曲强度和弹性模量分别为 27.8 ± 0.7 MPa 和 7.8 ± 0.2 GPa，断裂应变为 0.85 ± 0.05%。抗氧化和抗烧蚀试验是在气体动态流动和非平衡空气等离子加热条件下进行的，流速为 4.5-4.8 千米/秒，断裂焓为 45-50 兆焦/千克。在样品前表面临界点的 Tw = 1400-2700 °C 温度范围内进行加热。复合材料的平均线性烧蚀率和质量损失率分别为 6.3 ± 0.3 μm/s 和 6.22 ± 0.44 mg/s。传导系数的估计值为 0.280-0.285 W/（m K）。复合材料的性能源于钝化异质氧化物膜的形成和演化，该膜主要由铌酸钛 Ti2Nb10O29、Hf1-xTixO2、(Ti1-xHfx)1-yNbyOz 和 (Ti1-xHfx)NbO4 的混合溶液（均匀度范围较广）以及包裹的碳化物和硼化物颗粒组成。研究表明，随着工作温度的升高，复合材料的抗氧化性会增加，这是因为复合材料会通过一些相转变为液态。

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来源期刊

International Journal of Lightweight Materials and Manufacture Engineering-Industrial and Manufacturing Engineering

CiteScore

9.90

自引率

0.00%

发文量

审稿时长

48 days