Materials Reports  2021, Vol. 35 Issue (Z1): 389-394 |
| METALS AND METAL MATRIX COMPOSITES |
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| Application of Pack Cementation Technology in Nickel-based Superalloys |
| TANG Ziyuan1, ZHANG Shuting1, DU Kaiping2, XUAN Pengju1, SI Lina1
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1 Department of Materials Science and Engineering, North China University of Technology, Beijing 100144, China
2 BGRIMM Technology Group, Beijing 100160, China |
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Abstract Pack cementation is a widely used surface protection technology. The layer prepared by pack cementation has the advantages of good uniformity, good compactness and good adhesion with matrix, which can provide high-temperature oxidation resistance and thermal corrosion protection for parts in service at high temperature. In this paper, the embedding of impregnation agent was introduced, the research progress about cementation layer nickel-based superalloy material system was systematically reviewed, which from monopropellant aluminized to multiple sets of altogether permeability. The influence of different infiltration layer systems on the comprehensive properties of the coating at high temperature was compared, including Al, Al-Co, Al-Si ,Cr-Al, Pt-Al binary infiltration and rare earth compound infiltration. And also, the mechanism of rare earth in the pack cementation technology was discussed. The development direction of pack cementation technology was prospected in the end.
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Published: 16 July 2021
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| Fund:Jointly funded by Beijing Municipal Fund and Municipal Education Commission(KZ201910009010), North China University of Technology High-level Talent Research Startup Project(XN277), Yujie Team Project(XN212/009). |
| About author:: Ziyuan Tang graduated from the Hunan University of Humanities,Science and Technology in June 2018.She is currently a master student of the Department of Materials Science and Engineering,North China University of Technology.Her main research has focused on preparation of high temperature protective coating.Shuting Zhang received his Ph.D.degree in nonferrous metallurgy from Northeastern University in 2006.She is currently a professor and postgraduate supervisor in the Department of Materials Science and Engineering,North China University of Technology.She is mainly engaged in the design and calculation of high-quality metal and alloy powder composition, the research on the surface functionalization process and failure mechanism of high temperature hot end components of aircraft and ship engines, the research on 3D printing technology of alloy materials, etc. The application field of materials includes aviation and ship power metallurgy, etc.In the past five years, she has taken charge of and participated in nearly 30 national projects, including “The National Natural Science Foundation of China”, National Key R & D Program of China, “863” and “International Cooperation” projects, and 17 completed projects have won provincial and ministerial awards. She has published many papers in national and provincial core journals and applied for nearly 20 national invention patents. |
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