Research Progress on Detection Technology for Film Cooling Holes and Coating Defects of Turbine Blades

XIA Kailong; GE Chao; WANG Qiutong; HE Qing

doi:10.16080/j.issn1671-833x.2022.13.092

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Research Progress on Detection Technology for Film Cooling Holes and Coating Defects of Turbine Blades

更新时间：2025-10-30

- Research Progress on Detection Technology for Film Cooling Holes and Coating Defects of Turbine Blades
- Aeronautical Manufacturing Technology Vol. 65, Issue 13, Pages: 92-104(2022)
- 作者机构：
  
  1. 中国农业机械化科学研究院表面工程技术研究所,北京,100083
  2. 北京金轮坤天特种机械有限公司,北京,100083
- 作者简介：
- 基金信息：
- DOI：10.16080/j.issn1671-833x.2022.13.092
  CLC：
- Published：2022
- 稿件说明：
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夏凯龙，葛超，王秋童，何箐. 涡轮叶片冷却气膜孔及涂层缺陷检测技术研究进展[J]. 航空制造技术, 2022, 65(13): 92-104.

XIA Kailong，GE Chao，WANG Qiutong，HE Qing. Research Progress on Detection Technology for Film Cooling Holes and Coating Defects of Turbine Blades[J]. Aeronautical Manufacturing Technology, 2022, 65(13): 92-104.
夏凯龙，葛超，王秋童，何箐. 涡轮叶片冷却气膜孔及涂层缺陷检测技术研究进展[J]. 航空制造技术, 2022, 65(13): 92-104. DOI： 10.16080/j.issn1671-833x.2022.13.092.

XIA Kailong，GE Chao，WANG Qiutong，HE Qing. Research Progress on Detection Technology for Film Cooling Holes and Coating Defects of Turbine Blades[J]. Aeronautical Manufacturing Technology, 2022, 65(13): 92-104. DOI： 10.16080/j.issn1671-833x.2022.13.092.

摘要

为满足现代燃气涡轮发动机长寿命、高可靠性的需求，高性能涡轮叶片呈现出气膜冷却结构和热障涂层热防护一体化设计与制造的发展趋势。然而气膜孔制备过程产生的显微组织缺陷和涂层涂覆过程导致的尺寸偏差会影响气膜结构及其冷却效率，先涂层后飞秒激光制孔也会引起涂层局部烧结甚至开裂。叶片服役过程中，受到温度梯度和边缘效应的影响，孔边涂层更易产生应力集中进而导致裂纹的萌生扩展，成为失效的薄弱环节。目前，包括塞规法、流量法和微小探针法等传统测量手段均无法有效评估气膜孔尺寸参数、形状特征和加工缺陷。在各类用于叶片及其涂层质量评价的无损检测方法中，主动红外热成像法具有快捷、多功能和有效质量控制等优势。基于上述研究背景，本文综述了快速、高精度的气膜孔参数测量和孔边合金及涂层缺陷的评估方法，论述了燃气涡轮发动机涡轮叶片常见气冷结构及其制备工艺的发展，详细列举了主动式红外热成像技术用于气膜孔质量评价的研究进展，同时总结了现有技术的不足和发展方向，对提升涡轮叶片冷却结构和气膜孔加工质量控制水平具有重要意义。

Abstract

In order to meet the long-life and high-reliability requirements of modern gas turbine engines

the development trend of high-performance turbine blades is presented as integrated designing and manufacturing of film cooling structure and thermal barrier coating for thermal protection. However

the gas film structure and its cooling efficiency could be affected by the microstructure defects produced in the process of film holes preparation and the dimensional deviations caused by the coating. The progress of coating first will also cause local sintering or even cracking of the coating

with femtosecond laser drilling afterwards. During blade service

due to the temperature gradient and edge effects

the stress concentration of coating on the edge is more easily occurred

leading to the initiation and expansion of cracks

which becomes the weakness of failure. At present

traditional measurement methods

including the plug gauge method

flow method

and microprobe method

cannot effectively evaluate the geometric parameters

shape characteristics and processing defects of the film holes. Among the various non-destructive testing methods applied to evaluate the quality of blades and coatings

active infrared thermography is qualified of the advantages of high-speed

versatility and effective quality control. In this paper

a high-efficiency and high-precision parameters measurement and defect evaluation methods for alloy and coatings around the holes are reviewed in conjunction with traditional non-destructive testing methods and the development of common air-cooling structures and their preparation processes are discussed. The research progress of the application of active infrared thermal imaging technology in the evaluation of film cooling holes is enumerated in detail. At the same time

the article summarizes the deficiency and the development orientation of the current technology

which is of great significance for improving the processing quality control level of the gas cooling structures and film holes.

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Related Institution

Institute of New Materials, Guangdong Academy of Sciences

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