SiCf/SiC复合材料高温水氧腐蚀性能研究

采用2.5D方式编织SiCf/SiC复合材料预制体,CVI工艺制备PyC界面层,CVI-PIP复合工艺制备SiCf/SiC复合材料基体,在1300℃、50%水汽/50%O 2混合气体的条件下对SiCf/SiC复合材料进行高温水氧腐蚀试验,对SiCf/SiC复合材料在腐蚀前后的相成分变化及微观组织变化进行评价,并探讨了其在高温水氧腐蚀条件下的性能退化机理。结果表明,PyC界面层易被氧化生成气体产物从而留下间隙,该通道为外界腐蚀性气体如水汽、氧气进入复合材料内部侵蚀其纤维、基体等提供捷径。

等离子体喷涂环境障涂层高温失效研究进展

环境障涂层因具有良好的抗高温水氧腐蚀能力而备受关注,但是由于外部砂粒等对涂层表面的侵蚀作用,仅能满足抗水氧腐蚀,还不能达到未来航空器高温部端的要求,CMAS腐蚀是对环境障涂层的另一个挑战。环境障涂层多采用等离子体喷涂工艺制备。由于涂层在经历高低温冲击时,会不可避免地发生失效。针对这一事实,文中对涂层失效种类和失效方式进行了总结和归纳,同时还介绍了环境障涂层的产生和发展历程。从微观、介观到宏观的维度介绍了环境障涂层的选材;通过分析国内外在环境障涂层方面的研究结果,结合计算模拟对CMAS引起的失效、高温水蒸气引起的失效以及热冲击引起的失效,进行了详细的阐述并总结了相应的失效机理;最后指出了环境障涂层面向应用仍然需要解决的问题以及未来的研究趋势。

Si/(Yb_(1-x)Y_(x))_(2)Si_(2)O_(7)/LaMgAl_(11)O_(19)热/环境障涂层的高温性能研究

采用等离子喷涂法在碳化硅纤维增强碳化硅陶瓷基复合材料(SiC_(f)/SiC-CMCs)表面制备了Si/(Yb_(1-x)Y_(x))_(2)Si_(2)O_(7)/LaMgAl_(11)O_(19)(x=0、0.5)热/环境障涂层(T/EBCs)体系。通过SEM、EDS和XRD等测试方法研究了不同组成的T/EBCs体系在1300℃下的热循环性能和抗水氧腐蚀性能,进而探讨了热循环失效和水氧腐蚀失效机理。结果表明,在T/EBCs体系中,Si/Yb_(2)Si_(2)O_(7)/LMA涂层体系的热循环寿命为403次,抗水氧腐蚀性能为50 h,Si/YbYSi_(2)O_(7)/LMA体系的热循环寿命降低至277次,而水氧腐蚀性能提高至80 h。YbYSi_(2)O_(7)与LMA之间较大的热失配应力以及层间含Al化合物或固溶体的生成是Si/YbYSi_(2)O_(7)/LMA热循环寿命降低的主要原因;YbYSi_(2)O_(7)-EBCs层较少的杂质氧化物减少了与水反应生成挥发性物质的几率,提高了Si/YbYSi_(2)O_(7)/LMA的抗水氧腐蚀能力。

陶瓷基复合材料环境障涂层研究进展

本文阐述了用于陶瓷基复合材料表面防护的环境障涂层的工作机理及选材关键,列举了多种类型环境障涂层的抗氧化性能、高温水氧腐蚀性能、抗CMAS侵蚀性能的测试数据,得出以稀土硅酸盐作为面层的环境障涂层代表了未来环境障涂层发展的方向,稀土硅酸盐热膨胀系数差异造成的环境障涂层内残余应力的产生以及粘结层的氧化是导致涂层过早剥落失效的主要原因等结论,并论述了当前国内EBC涂层的研究发展,以期为未来航空发动机用环境障涂层材料的选择和高温水氧腐蚀的防护提供有益参考。

(Yb_(0.25)Lu_(0.25)Er_(0.25)Y_(0.25))_(2)Si_(2)O_(7)高熵硅酸盐热环境障涂层的性能研究

通过高熵化设计制备了一种新型焦硅酸盐涂层材料(Yb_(0.25)Lu_(0.25)Er_(0.25)Y_(0.25))_(2)Si_(2)O_(7),采用大气等离子喷涂(APS)在碳化硅纤维增强碳化硅陶瓷复合材料(SiC_(f)/SiC-CMCs)表面制备了(4RE_(0.25))_(2)Si_(2)O_(7)一体化热环境障涂层(TEBCs)体系和LaMgAl_(11)O_(19)/Lu_(2)Si_(2)O_(7)热/环境障涂层(T/EBCs)体系。通过研究两种涂层体系的微观结构、热物理性能、水氧腐蚀性能以及热循环寿命等结果发现:APS制备的(4RE_(0.25))_(2)Si_(2)O_(7)涂层从室温到1500℃为稳定的β相,(4RE_(0.25))_(2)Si_(2)O_(7)涂层不存在成分偏析,热导率和热膨胀系数相对Lu_(2)Si_(2)O_(7)涂层有所降低,更适合作为一体化TEBCs使用;(4RE_(0.25))_(2)Si_(2)O_(7)TEBCs体系的水氧腐蚀寿命高于80 h,LaMgAl_(11)O_(19)/Lu_(2)Si_(2)O_(7)T/EBCs体系的水氧腐蚀寿命低于80 h;(4RE_(0.25))_(2)Si_(2)O_(7)TEBCs体系的热循环寿命为168次;高熵化设计使焦硅酸盐涂层CTE适配度提高,断裂韧性增强,进而增加了TEBCs体系的热循环寿命。

High Temperature Corrosion of Water Wall Materials T23 and T24 in Simulated Furnace Atmospheres

Candidate materials for water wall of supercritical and ultra-supercritical utility boilers,T23 and T24,were chosen as the experimental samples and exposed to oxidizing atmosphere,reducing atmosphere and oxidizing/reducing alternating atmosphere separately.The corrosion temperature was 450-550?C.The effects of oxygen con-tent and temperature on the corrosion in reducing atmosphere and alternating atmosphere were investigated.The scanning electron microscope(SEM) and energy dispersive spectrometer(EDS) were used to examine the corroded samples.The results show that the corrosion kinetics of T23 and T24 can be described by the double logarithmic equation and parabolic equation respectively.To describe the corrosion of materials accurately it is not sufficient to analyze the macro-mass gain and the macro-thickness of the corroded layer only,but the EDS should be applied to examine the migration depth of corrosive elements O and S.It is revealed that the corrosion becomes more severe when H2S is present in the corrosive gas.S is more active than O,and Cr can reduce the migration of oxygen but not S.The combination corrosion of S and O and pure [S] has a stronger corrodibility than pure H2S.T24 suffers the most severe corrosion at oxygen content of 0.8%.Corrosion is aggravated when the corrosion temperature is above 450 ℃ in the alternating atmosphere.T23 has better corrosion resistance than T24 and W contributes a lot to the corrosion resistance of T23.