不同激光加工工艺的DD406单晶高温合金气膜孔高温氧化行为

Yizhe Yang, Zhao Yang, Yunsong Zhao, Haiqing Pei, Meng Li, Yanqiu Yang, Zhixun Wen, Zhufeng Yue

科研成果: 期刊稿件文章同行评审

摘要

Turbine blades of long-life civil aircraft and gas turbines are affected by high temperature oxidation during service, which greatly reduces the surface strength under complex working conditions and significantly shortens the service life. Therefore, oxidation resistance is one of the most specific properties that must be considered in the application of turbine blades. The influence of the different drilling processes for cooling holes on the oxidation behavior of Ni-based SX (single-crystal) superalloy at 980℃ and 1100 ℃ was investigated. The difference in the oxidation mechanism of the cooling holes under different drilling processes provided a basis for the establishment of the blade life model under service conditions. The results indicate that the film cooling holes processed by millisecond laser exhibit poor oxidation performance, and all oxidation kinetic curves basically obey the parabolic or linear law. In the initial oxidation stage of the millisecond laser specimen, the oxidation reaction is primarily determined by the growth pattern of outer NiO. Subsequently, a three-layer oxide layer((Ni, Co)O-Spinel phase layer-α-Al2O3) gradually formed around the hole. There are relatively micro-holes under the internal α-Al2O3 layer and the γ'-free zone, which makes the oxide layer easy to exfoliate. Discontinuous α-Al2O3 is rapidly formed in the initial oxidation stage of the picosecond laser specimen, and then connected to each other to form the dense α-Al2O3 layer.

投稿的翻译标题High temperature oxidation behavior of DD406 SX superalloy film cooling holes with different laser drilling processes
源语言繁体中文
页(从-至)29-40
页数12
期刊Hangkong Cailiao Xuebao/Journal of Aeronautical Materials
42
2
DOI
出版状态已出版 - 4月 2022

关键词

  • DD406 single-crystal superalloy
  • Laser drilling
  • Oxidation kinetic
  • Oxidation mechanism
  • Turbine blade film cooling holes

指纹

探究 '不同激光加工工艺的DD406单晶高温合金气膜孔高温氧化行为' 的科研主题。它们共同构成独一无二的指纹。

引用此