热障涂层激光表面处理技术研究现状和发展趋势

阚生盼; 王大锋; 刘顺平; 王超越; 张咪娜; 周香林

doi:10.16490/j.cnki.issn.1001-3660.2026.02.006

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表面技术 ›› 2026, Vol. 55 ›› Issue (2) : 61-79. DOI: 10.16490/j.cnki.issn.1001-3660.2026.02.006

激光表面改性技术

热障涂层激光表面处理技术研究现状和发展趋势

阚生盼^1,2, 王大锋^2,*, 刘顺平¹, 王超越¹, 张咪娜³, 周香林^1,*

作者信息 +

Research Status and Development Trends of Laser Surface Treatment Technique for Thermal Barrier Coatings

KAN Shengpan^1,2, WANG Dafeng^2,*, LIU Shunping¹, WANG Chaoyue¹, ZHANG Mina³, ZHOU Xianglin^1,*

Author information +

文章历史 +

摘要

热障涂层是航空发动机关键高温防护材料。在热-力-化多场耦合环境下,孔隙、微裂纹等典型缺陷易诱发热腐蚀介质的渗透,导致涂层失效破坏。采用激光表面处理技术对热障涂层表面进行加工或改性处理,能够细化晶粒,提升涂层结构致密度、表面组织均匀性,是增强热障涂层耐热腐蚀性能和服役寿命的重要手段之一。本文概述了热障涂层目前常用的材料、结构、制备工艺优势及问题,重点综述不同激光表面处理技术（激光上釉、激光重熔、激光刻蚀）对热障涂层的表面质量、耐高温腐蚀性能、抗热震性能及力学性能等方面的影响,同时探讨激光表面处理因热应力而产生的网状裂纹,虽会提升涂层的应变容限,但会成为高温下热腐蚀介质渗入涂层内部通道的问题,总结出高能量短波长激光器上釉、激光釉层/重熔层结构改性、掺杂自愈合材料、填充裂纹四种改善方式。最后,在指出当前激光表面处理热障涂层技术局限性的基础上,从新型多元陶瓷热障涂层、新型激光器与多种激光工艺对热障涂层的复合处理、搭建激光表面处理集成平台等方向展望其未来发展趋势。

Abstract

With the continuous development of aero-engines and gas turbines towards higher thermal efficiency, their internal operating temperatures and pressures keep increasing, imposing more stringent requirements on high-temperature protective materials. Thermal barrier coatings (TBCs), owing to their unique multi-layered structure and excellent high-temperature performance, have become critical materials for ensuring the reliable operation of hot-end components, garnering extensive attention and application. However, under the harsh service environment involving thermal-mechanical-chemical multi-field coupling, inherent defects within the coating, such as pores and microcracks, easily become channels for the infiltration of hot corrosion media, triggering CMAS corrosion (mainly composed of CaO, MgO, Al₂O₃, SiO₂) and molten salt corrosion (e.g., V₂O₅, Na₂SO₄). These corrosion processes often lead to phase transformations and the formation of new compounds in the coating, generating stresses that cause coating spallation and failure. To address this challenge, laser surface treatment technique has emerged. Through precise processing and modification of the coating surface, it effectively refines grains, enhances density, and improves microstructural homogeneity, thereby significantly improving the hot corrosion resistance and service life of TBCs. Therefore, it has become an important technical approach for optimizing coating performance.
The work aims to outline the commonly used materials, structures, and preparation processes for TBCs, highlighting their advantages and limitations and then provide a comprehensive review on the effects of different laser surface treatment techniques on the surface quality, high-temperature corrosion resistance, thermal shock resistance, and mechanical properties of TBCs. Based on the process characteristics and application objectives of laser surface treatment for TBCs, the techniques are categorized into three types, including laser glazing, laser remelting, and laser etching. Laser glazing utilizes high-energy laser irradiation on the coating surface to achieve ultra-rapid melting and solidification of the surface micro-region, forming a thin, dense microcrystalline or amorphous layer (with a thickness ranging from several micrometers to tens of micrometers). Technically, it is a special form of laser remelting, making it more suitable for scenarios with stringent surface performance requirements. In contrast, traditional laser remelting involves greater processing depth, larger melt pool volumes, and thicker remelted layers, which is prone to significant thermal stress and the formation of high-density cracks. Laser etching, on the other hand, uses laser selective ablation to create specific microstructures on the coating surface, thereby altering the physical properties of the coating.
To better illustrate the effect of laser glazing in enhancing the hot corrosion resistance of TBCs, its benefits are analyzed from three aspects such as improvement in coating surface quality and formation of a densified surface layer structure. The corresponding failure mechanisms are also summarized. Additionally, the issue of network cracks induced by thermal stress during laser surface treatment is discussed. While these cracks can enhance the strain tolerance of the coating, they may also serve as channels for hot corrosion media to penetrate the coating interior at high temperatures. Four improvement strategies are identified, including glazing with high-energy, short-wavelength lasers, structural modification of the glazed or remelted layer, doping with self-healing materials and crack filling.
Finally, the current limitations of laser surface treatment for TBCs are pointed out. For instance, existing research primarily focuses on traditional YSZ ceramic layers, while studies on laser surface treatment of new materials such as rare-earth-doped zirconia/high-entropy ceramics are still insufficient and controlling the temperature field and residual stresses during laser processing remains a major challenge. Based on this, future development trends are prospected, including novel multi-component ceramic TBCs, composite treatment of TBCs with new laser sources and multiple laser processes, and the establishment of integrated laser surface treatment platforms.

导出引用

阚生盼, 王大锋, 刘顺平, 王超越, 张咪娜, 周香林. 热障涂层激光表面处理技术研究现状和发展趋势[J]. 表面技术. 2026, 55(2): 61-79

KAN Shengpan, WANG Dafeng, LIU Shunping, WANG Chaoyue, ZHANG Mina, ZHOU Xianglin. Research Status and Development Trends of Laser Surface Treatment Technique for Thermal Barrier Coatings[J]. Surface Technology. 2026, 55(2): 61-79

中图分类号： TG174.4

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