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用于高温应用的冷喷涂镍钴铬铝X(X =钇、铪和硅)粘结层

NiCoCrAlX (X = Y, Hf and Si) Bond Coats by Cold Spray for High Temperature Applications.

作者信息

Cojocaru Cristian V, Aghasibeig Maniya, Irissou Eric

机构信息

National Research Council of Canada, Boucherville, QC Canada.

出版信息

J Therm Spray Technol. 2022;31(1-2):176-185. doi: 10.1007/s11666-022-01322-2. Epub 2022 Feb 14.

DOI:10.1007/s11666-022-01322-2
PMID:37520910
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8853232/
Abstract

MCrAlX powder compositions (M = Ni,Co and X = Y, Hf, Si or combination) are often thermally sprayed via vacuum plasma spray (VPS), low pressure plasma spray (LPPS) or high velocity oxy-fuel to produce high temperature oxidation and hot corrosion resistant bond coats for thermal barrier coatings (TBCs). Cold spray technology is currently considered as a promising alternative to the traditional thermal spray solutions, having the advantage of delivering oxide-free and very dense metallic coatings at relatively lower costs compared to VPS and LPPS. NiCoCrAlY and NiCoCrAlYHfSi bond coats were deposited using a high pressure cold spray system and the influence of feedstock properties on the deposited bond coats were investigated. To improve NiCoCrAlYHfSi bond coat deposition, laser assisted cold spray (LACS) was employed. The results show that LACS can be successfully used to deposit this particular powder while eliminating nozzle erosion and low deposition efficiency disadvantages observed with conventional cold spray. To identify the optimal LACS setup for deposition of dense and uniform coatings, different laser/spray jet configurations were examined. TBCs with bond coats sprayed at the optimal configuration were assessed isothermally at 1150 °C in air for up to 500 h, and the results showed formation of a thermally grown oxide layer composed of predominantly AlO with embedded small clusters of Hf-Y-rich oxides.

摘要

MCrAlX粉末组合物(M =镍、钴,X =钇、铪、硅或其组合)通常通过真空等离子喷涂(VPS)、低压等离子喷涂(LPPS)或高速氧燃料喷涂进行热喷涂,以生产用于热障涂层(TBC)的耐高温氧化和抗热腐蚀粘结层。冷喷涂技术目前被认为是传统热喷涂解决方案的一种有前途的替代方法,与VPS和LPPS相比,它具有以相对较低的成本提供无氧化物且非常致密的金属涂层的优点。使用高压冷喷涂系统沉积了NiCoCrAlY和NiCoCrAlYHfSi粘结层,并研究了原料特性对沉积粘结层的影响。为了改善NiCoCrAlYHfSi粘结层的沉积,采用了激光辅助冷喷涂(LACS)。结果表明,LACS可以成功地用于沉积这种特定粉末,同时消除了传统冷喷涂中观察到的喷嘴侵蚀和低沉积效率缺点。为了确定用于沉积致密且均匀涂层的最佳LACS设置,研究了不同的激光/喷射配置。对在最佳配置下喷涂粘结层的TBC在空气中1150°C下进行了长达500小时的等温评估,结果表明形成了主要由AlO组成的热生长氧化层,其中嵌入了富含Hf-Y的小氧化物簇。

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