SiC/Si-B-C复合材料的抗水氧腐蚀性能及行为OA
Water-Oxygen Corrosion Resistance and Behavior of SiC/Si-B-C Composite Materials
SiC/Si-B-C复合材料具有低密度、高比模量和强度、高韧性、抗氧化等优异特性,已成为航空、航发等领域热端部件极具潜力的关键材料,且高温水氧环境是其典型的服役环境.该文系统研究了硼改性2.5D SiC/Si-B-C复合材料在1 100℃、高水氧分压(90 kPa H₂O-10 kPa O₂)极端水氧环境中经50、100、150、200、250和300 h腐蚀后的性能演变与损伤机制.通过分析材料腐蚀前后的密度、显气孔率、室温弯曲性能及微观结构,发现:在初期(≤200 h)腐蚀阶段,材料性能保持稳定,弯曲强度保留率超过97%,显气孔率略有下降,硼元素通过形成硼硅酸盐玻璃相实现动态自愈合,有效延缓氧化介质侵入;而在长期(300 h)腐蚀后,材料性能发生显著退化,弯曲强度保留率骤降至40%,显气孔率升至5.2%,断口纤维拔出长度显著缩短,呈现脆性断裂特征.微观分析表明,硼的持续挥发导致基体疏松化,并促使表面CVD(化学气相沉积工艺)SiC涂层由"菜花状"结构转变为熔融玻璃态且产生宏观裂纹,丧失屏障功能.研究揭示了硼改性SiC/SiC复合材料在长时极端水氧环境下可能的性能退化机制,为其工程化应用提供了理论依据.
SiC/Si-B-C composite materials,with their excellent properties including low density,high specific modulus and strength,high toughness,and oxidation resistance,have become highly promising key materials for hot-section components in aviation and aerospace propulsion system.High-temperature water-oxygen environments con-stitute their typical service conditions.This paper systematically investigates the performance evolution and da-mage mechanism of boron-modified 2.5D SiC/Si-B-C composites exposed to an extreme water-oxygen environment(90 kPa H₂O-10 kPa O₂)at 1100℃for corrosion durations of 50,100,150,200,250,and 300 hours.By analyzing the density,apparent porosity,room-temperature flexural properties and microstructure of the materials before and after corrosion,the following findings are obtained.In the initial corrosion stage(≤200 h),the material properties remain stable,with flexural strength retention exceeding 97%and a slight decrease in apparent porosity.Boron achieves dynamic self-healing through the formation of a borosilicate glass phase,effectively delaying the invasion of the oxidizing media.However,after long-term(300 h)corrosion,the material properties undergo significant degradation,with the flexural strength retention rate sharply dropping to 40%and apparent porosity increasing to 5.2%.The fiber pull-out length at the fracture surface is markedly reduced,presenting brittle fracture characteristics.Microscopic analysis reveals that the continuous volatilization of boron leads to matrix loosening and causes the surface CVD SiC coating to transform from a cauliflower-like structure into a molten glassy state with macroscopic cracks thereby losing its barrier function.This study reveals the possible performance degradation mechanism of boron-modified SiC/SiC composites in long-term extreme water-oxygen environments,providing a theoretical basis for their engineering applications
刘时剑;李琼云;徐昊;陈义;张冰玉;陈明伟;邱海鹏;于倩倩;王林格
中国航空制造技术研究院 复合材料技术中心,北京 101300||华南理工大学 前沿软物质学院,广东 广州 510640中国航空工业集团公司 成都飞机设计研究所,四川 成都 610041中国航空制造技术研究院 复合材料技术中心,北京 101300中国航空制造技术研究院 复合材料技术中心,北京 101300中国航空制造技术研究院 复合材料技术中心,北京 101300中国航空制造技术研究院 复合材料技术中心,北京 101300中国航空制造技术研究院 复合材料技术中心,北京 101300华南理工大学 前沿软物质学院,广东 广州 510640华南理工大学 前沿软物质学院,广东 广州 510640
化学化工
SiC/Si-B-C复合材料水氧腐蚀自愈合强度保留率显气孔率
SiC/Si-B-C compositeswater-oxygen corrosionself-healingstrength retention rateapparent porosity
《华南理工大学学报(自然科学版)》 2026 (5)
147-156,10
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