APS 8YSZ/NiCrAlY热障涂层的制备与高温水氧腐蚀行为研究OA
Preparation and High-temperature Water-oxygen Corrosion Behavior of APS 8YSZ/NiCrAlY Thermal Barrier Coatings
目的 随着"国家双碳战略"的实施,以纯氢或掺氢为燃料的燃气轮机越来越引起重视,随之而来的热端部件的热障涂层的高温水氧腐蚀行为也日趋严重.为了阐明 8YSZ热障涂层在高温水氧腐蚀和大气气氛下的氧化行为区别,本文采用大气等离子喷涂技术制备了 8YSZ/NiCrAlY 热障涂层.方法 采用 SEM、XRD、Raman 等表征手段对高温水氧腐蚀和大气气氛下的氧化后涂层的微观组织结构和氧化动力学进行表征.结果 经过水氧腐蚀和氧化后,陶瓷层均由大量的t'-ZrO2 和少量m-ZrO2组成.水氧腐蚀后的 8YSZ表面有粉化现象且随着腐蚀时间的增加,粉化程度逐渐加重,截面在腐蚀 50 h时可以观察到TGO层有黑色和灰色两种衬度的存在,随着腐蚀时间的增加,黑色衬度层变得薄且不连续.氧化后的 8YSZ表面与制备态涂层表面相比没有明显的变化.在大气气氛氧化 50 h 时,TGO 层中的黑色衬度层已很薄且不连续.结论8YSZ/NiCrAlY TBC 水氧腐蚀后,m-ZrO2 相含量增加是因为高温环境下晶体的密排结构遭到了破坏,导致8YSZ从t'相向m相转化.水氧腐蚀出现表面粉化现象的原因是因为高温水氧环境下,水蒸气与表面发生反应生成易分解的 ZrO(OH)2 和 Y(OH)3 等氢氧化物,破坏涂层的表面使其粉化.在水氧腐蚀前期水蒸气的存在可能会促进Al2O3的生成,使TGO层增厚速率更快;TGO层中黑色衬度层以Al2O3为主,灰色衬度层主要为Cr2O3、NiO或Ni(Cr,Al)2O4等氧化物.随着水氧腐蚀时间的增加,水蒸气会导致TGO层出现多孔化现象,致使Al2O3挥发进而导致出现局部失重现象,水氧腐蚀的增重曲线表现出低于氧化行为.因此,亟需研制抗高温水氧腐蚀涂层.
With the implementation of the"National Dual-carbon Strategy",gas turbines using pure hydrogen or hydrogen-blended fuels have attracted increasing attention.Consequently,the high-temperature water-oxygen corrosion behavior of thermal barrier coatings on hot-end components has become increasingly serious.However,in recent years,there are still few reports on influences of the presence or absence of water vapor on the micro-structural evolution and oxidation kinetics behavior of YSZ thermal barrier coatings at high temperature.In order to clarify the difference in the oxidation behavior of 8YSZ thermal barrier coatings under high-temperature water-oxygen corrosion and atmospheric conditions,and to provide a preliminary basis for the research on the water-oxygen corrosion resistance of high-performance thermal barrier coatings,8YSZ/NiCrAlY thermal barrier coatings were prepared by atmospheric plasma spraying.Scanning electron microscopy(SEM),X-ray diffraction(XRD),and Raman spectroscopy were used to characterize the microstructure and oxidation kinetics of the coatings after high-temperature heat treatment under water-oxygen corrosion and air atmosphere,respectively.The results showed that the ceramic layer was mainly composed of t'-ZrO2 and a small amount of m-ZrO2 after water-oxygen corrosion and oxidation.Compared with the as-prepared coating,there was an obvious powdering phenomenon on the surface of the 8YSZ coating after water-oxygen corrosion,and the degree of powdering increased with the increase of corrosion time.A TGO layer could be observed in the cross-sectional morphology after water-oxygen corrosion for 50 h.A black-contrast layer and a gray-contrast layer could be observed in the TGO layer.At this time,the black-contrast layer was thick and continuous,but as the corrosion time increased,the black-contrast layer became thin and discontinuous.There was no obvious change on the surface of the oxidized 8YSZ coating compared with the as-prepared coating.When oxidized in the atmosphere for 50 h,the black-contrast layer in the TGO layer was already very thin and discontinuous.As the oxidation time increased to 100 h,the black-contrast layer could hardly be observed.Analysis and summary of the above phenomena lead to the following conclusions:In a high-temperature water-oxygen environment,water vapor reacts with the surface 8YSZ to form easily decomposable hydroxides such as Zr(OH)4 and Y(OH)3,which destroys the coating surface and causes powdering.The black-contrast layer in the TGO layer is mainly composed of Al2O3,and the gray-contrast layer is mainly composed of oxides such as Cr2O3,NiO,or Ni(Cr,Al)2O4.In the early stage of water-oxygen corrosion,the presence of water vapor might promote the formation of Al2O3,making the growth rate of the TGO layer faster.This is manifested by an obvious contrast distribution in the TGO layer,and the thickness of the TGO layer is larger than that after oxidation in the atmosphere for the same time.As the water-oxygen corrosion time increases,water vapor would cause the TGO layer to become porous,resulting in the volatilization of Al2O3 and local weight loss.The weight-gain curve of water-oxygen corrosion is lower than that of oxidation.Therefore,it will be urgent to develop coatings resistant to high-temperature water-oxygen corrosion.
赵孝通;马培龙;薛召露;张振亚;何健;张世宏
安徽工业大学 先进金属材料绿色制备与表面技术教育部重点实验室,安徽 马鞍山 243002安徽工业大学 先进金属材料绿色制备与表面技术教育部重点实验室,安徽 马鞍山 243002安徽工业大学 先进金属材料绿色制备与表面技术教育部重点实验室,安徽 马鞍山 243002安徽工业大学 先进金属材料绿色制备与表面技术教育部重点实验室,安徽 马鞍山 243002北京航空航天大学 材料智能设计国家级重点实验室,北京 102206安徽工业大学 先进金属材料绿色制备与表面技术教育部重点实验室,安徽 马鞍山 243002
矿业与冶金
热障涂层大气等离子喷涂8YSZ高温水氧腐蚀行为
thermal barrier coatingsatmospheric plasma spraying8YSZhigh-temperature water-oxygen corrosion behavior
《表面技术》 2026 (3)
61-71,11
国家自然科学基金(52571058)材料智能设计国家级重点实验室开放课题基金(2025B05) National Natural Science Foundation of China(52571058)Open Project Program of State Key Laboratory of Artificial Intelligence for Materials Science(2025B05)
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