材料科学
化学气相渗透
复合材料
抗弯强度
热解炭
微观结构
碳化硅
碳化
热解
扫描电子显微镜
固化(化学)
热压
化学工程
工程类
作者
Lin-tao Jia,Mengqian Wang,Xiaofeng Guo,Jie Zhu,Aijun Li,Yuqing Peng
标识
DOI:10.1016/s1872-5805(23)60732-2
摘要
Carbon/carbon-silicon carbide (C/C-SiC) composites were prepared by impregnation, hot-pressing with curing, carbonization at 800 oC and high-temperature heat treatment (800-1600 oC) using a 2D laminated carbon cloth as the reinforcing filler, and furfurone resin mixed with silicon, carbon from furfurone resin and SiC powders as the matrix. The effects of the addition of the three powders as well as subsequent chemical vapor infiltration (CVI) by methane on the density, microstructure and bend strength of the composites were investigated by scanning electron microscopy, density measurements, X-ray diffraction and mechanical testing. Both the SiC powders formed by the reaction at 1 600 oC between the added Si and C particles and the added SiC powder, play a role in the reinforcement of the materials. In three-point bending, the composites had a pseudoplastic fracture mode and showed interlaminar cracking. After 10 h CVI with methane, pyrolytic carbon was formed at the interface between some of the carbon fibers and the resin carbon matrix, which produced maximum increases in the density and flexural strength of the composites of 4.98% and 38.86%, respectively.
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