| 引用本文: | 贺文燮,李伟,姜肃猛,宫骏,孙超.NiRe层对NiAl涂层抗氧化性能的影响[J].中国表面工程,2024,37(5):305~313 |
| HE Wenxie,LI Wei,JIANG Sumeng,GONG Jun,SUN Chao.Effect of NiRe Layer on Oxidation Resistance of NiAl Coatings[J].China Surface Engineering,2024,37(5):305~313 |
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| 摘要: |
| 在 β-NiAl 涂层中添加改性元素仍是目前的研究热点,但关于活性元素(Re)改性 β-NiAl 的研究较少。为了探究 NiRe 层对铝化物涂层抗氧化性能的影响,对比评价 Al 扩散涂层和 1Re-NiAl 涂层在 1 100 ℃时的恒温氧化行为。利用扫描电子显微镜和 X 射线衍射仪对涂层的截面、表面形貌以及组织演变过程进行分析。研究结果表明,Al 扩散涂层的 Zone 1 和 Zone 2、 1Re-NiAl 涂层的 Zone 2 基本都由 β-NiAl 相和白色的 α-W 析出相构成,1Re-NiAl 涂层外层的 Zone 1 则由 β-NiAl 相和白色的 γ-Re 析出相构成;恒温氧化 300 h 后,1Re-NiAl 涂层的氧化总增重值为 0.62 mg / cm2 ,低于 Al 扩散涂层的氧化总增重 (2.77 mg / cm2 );Al 扩散涂层发生严重的内氧化和氧化膜剥落,1Re-NiAl 涂层仅发生轻微的氧化膜剥落;涂层中添加电镀 NiRe 层后显著提高涂层的抗氧化性能。通过电镀和电弧离子镀相结合的工艺成功引入 Re,并研究 NiRe 层对涂层抗氧化性能的影响,可为后续深入研究 Re 及其他元素改性的 β-NiAl 涂层提供新思路。 |
| 关键词: NiRe 复合镀 电弧离子镀 β-NiAl 涂层 恒温氧化 |
| DOI:10.11933/j.issn.1007-9289.20240309001 |
| 分类号:TG156;TB114 |
| 基金项目: |
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| Effect of NiRe Layer on Oxidation Resistance of NiAl Coatings |
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HE Wenxie1,LI Wei2,JIANG Sumeng2,GONG Jun2,SUN Chao2
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1.Special Machining Center, Guiyang AECC Power Precision Casting Co.LTD., Guiyang 550014 , China ;2.Division of Surface Engineering of Materials, Institute of Metal Research, Chinese Academy of Sciences,Shenyang 110016 , China
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| Abstract: |
| Owing to their excellent high-temperature mechanical properties, nickel-based superalloys have been widely used in aviation, particularly in the hot end-components of aeroengines. Al and Cr contribute significantly to the oxidation resistance and thermal corrosion resistance of superalloys; however, they adversely affect the microstructure stability and plasticity of superalloys. Owing to the continuous development of superalloys, the proportions of these two elements are decreasing, thus resulting in a decline in the corrosion resistance of superalloys. To improve the oxidation resistance and thermal corrosion resistance of superalloys, researchers have adopted high-temperature protective coatings in superalloys, which endow excellent comprehensive mechanical properties to the latter. β-NiAl has a high melting point and its Al content is higher than the critical concentration for the selective oxidation of aluminum; thus, it is the main forming phase of simple aluminide coatings. The addition of modified elements into β-NiAl coatings is being actively investigated, whereas studies regarding the Re modification of β-NiAl coatings are few. The method of electroplating NiRe, arc ion plating Al and vacuum heat treatment is adopted to perform Re modification on β-NiAl. To investigate the effect of the NiRe layer on the oxidation resistance of aluminide coatings, the isothermal oxidation properties of Al-diffusion and 1Re-NiAl coatings at 1 100 ℃ are evaluated. The cross-sectional, surface-morphology, and microstructural evolution of the coatings are analyzed via scanning electron microscope (SEM) and X-ray diffraction (XRD). Both coatings are primarily composed of the β-NiAl phase, whereas Zones 1 and 2 of the Al-diffusion coating and Zone 2 of the 1Re-NiAl coating are composed of β-NiAl and white α-W precipitated phases. Similarly, Zone 1 of the outer layer of the 1Re-NiAl coating is composed of β-NiAl and white γ-Re precipitated phases, thus indicting that the formation of α-W can be avoided by incorporating a NiRe layer. The isothermal oxidation kinetic results show that the total mass gain of the 1Re-NiAl coating is 0.62 mg / cm2 after isothermal oxidation for 300 h, which is lower than that of the Al-diffusion coating (2.77 mg / cm2 ). A significant amount of β-NiAl and slight oxide-scale spallation are indicated for the 1Re-NiAl coating. However, the diffraction peak of the β-NiAl phase cannot be detected and oxide-scale spallation on the surface is particularly severe in the Al-diffusion coating after isothermal oxidation for 150 h. The Al-diffusion coating shows severe internal oxidation and oxide-scale spallation (composed primarily of NiAl2O4 spinel), whereas the surface oxide scale of the 1Re-NiAl coating comprises single Al2O3 and indicates slight spallation after isothermal oxidation for 300 h. In the annealing process of the 1Re-NiAl coating, Al first diffuses into the NiRe layer, thus resulting in a gradual increase in Al content in the NiRe layer and a transformation into the β-NiAl phase. Simultaneously, the Re in the original NiRe layer is precipitated in situ to form a Re-rich precipitated phase in the outer layer of Zone 1 owing to the extremely low solid solubility of Re in β-NiAl. Thus, the incorporation of the electroplated NiRe layer can restrain the formation of α-W precipitates in the outer layer of the 1Re-NiAl coating. Moreover, incorporating Re improves the stability of the β-NiAl phase during oxidation and promotes Al diffusion from the inside to the surface of the coating. Thus, the oxidation resistance is improved significantly by incorporating an electroplated NiRe layer. In this study, Re is successfully introduced via electroplating and arc ion plating, and the effect of the NiRe layer on the oxidation resistance of the coating is investigated, which can facilitate future studies regarding Re and other element-modified β-NiAl coatings. Additionally, the reported method has broad application prospects. |
| Key words: composite electroplated NiRe arc ion plating β-NiAl coating isothermal oxidation |
