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SiC纤维增强SiC高温结构吸波材料研究现状
作者:丁冬海1 2  晶1 肖国庆1 
单位:(1. 西安建筑科技大学材料与矿资学院 西安710055 2. 西安建筑科技大学材料科学与工程博士后流动站 西安710055) 
关键词:碳化硅纤维预制体 界面层 基体 高温吸波性能 
分类号:TQ174
出版年,卷(期):页码:2019,47(1):0-0
DOI:10.14062/j.issn.0454-5648.2019.01.20
摘要:

 高温结构吸波材料集吸波、防热、承载于一体,其发展对实现航空航天器雷达隐身至关重要。连续SiC纤维增强SiC(SiCf/SiC)高温结构吸波材料具有高温抗氧化、断裂韧性高、阻抗与空气容易匹配等优点,被认为是最有前途的高温结构吸波材料之一。本文主要从SiC纤维预制体、界面层、基体3个方面对SiCf/SiC高温结构吸波材料改性研究现状进行评述,然后介绍SiCf/SiC高温结构吸波材料介电温度响应特性的研究进展,总结了SiCf/SiC高温结构吸波材料存在的问题并指明未来潜在的研究方向。

 High-temperature structural microwave absorbing materials integrate microwave absorbing performance, heat protecting performance and load-carrying capacity. The development of high-temperature structural absorbing materials is crucial for aerospace radar stealth. Continuous SiC fiber reinforced SiC(SiCf/SiC) high-temperature structural microwave absorbing material with high temperature oxidation resistance, high fracture toughness, impedance easy to match the air, etc., is considered as one of the most promising high-temperature structural absorbing materials. In this review, the research aspects (i.e., SiC fiber preform, interface layer and matrix) of SiCf/SiC high-temperature structural absorbing materials modification was represented. The research progress of the dielectric temperature response characteristics of SiCf/SiC high-temperature structural microwave absorbing material was introduced. The existing problems of SiCf/SiC high-temperature structural absorbing materials and the potential research directions in the future were given.

基金项目:
国家自然科学基金(51502236,51572212,51772236);中国博士后基金(2016M602940XB)资助项目
作者简介:
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