SiCf/SiC复合材料锥孔飞秒激光加工方法

doi:10.7527/S1000-6893.2025.31555

Abstract

Abstract:

Ceramic matrix composites stand out for excellent mechanical properties and high temperature resistance， making them promising for hot-end components of aircraft engines. However， due to their high hardness， brittleness， and low conductivity， processing conical film cooling holes with small aperture， large aspect ratio， and variable cross section has become a challenge. Femtosecond laser processing is an effective solution to this problem. Based on the conical hole structure， both positive and negative helical path were designed， and a two-step rotary drilling method using an inclined laser beam is adopted to achieve high-quality machining of positive and negative conical holes in SiC_f/SiC composite materials. The dimensional error of the conical hole entrance and exit is ≤ 10 μm， and the taper error is ≤ 0.1°； the entrance edges were covered with a small amount of deposition， while the exit is free of deposition and has sharp edge. The wall morphology of both the positive and negative conical holes is uniform， with fibers and matrix structures uniformly removed. The surface roughness （Sa） of the hole walls is approximately 1.8 μm for the positive conical hole and 2.5 μm for the negative conical hole. The formation process of the conical holes is studied， and the evolution of the bottom morphology and entrance/exit dimensions is analyzed. The hole profile formation mechanism is clarified， providing a processing foundation and quality evaluation reference for high-quality machining of conical holes in SiC_f/SiC composite hot-end components.

Key words: ceramic matrix composites, laser processing, conical hole, processing quality, formation mechanism

CLC Number:

V261.8

Zhaoji LI, Zhigang DONG, Feng YANG, Yan BAO, Renke KANG, Jiansong SUN. Femtosecond laser processing method for conical holes in SiC_f/SiC composites[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(10): 431555.

Figures/Tables 15

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References 34

1	PADTURE N P. Advanced structural ceramics in aerospace propulsion‍［J］. Nature Materials， 2016， 15（8）： 804-809.
2	焦健，孙世杰，焦春荣，等. SiC_f/SiC复合材料涡轮导向叶片研究进展［J］. 复合材料学报， 2023， 40（8）： 4342-4354.
	JIAO J， SUN S J， JIAO C R， et al. Research progress of SiC_f/SiC turbine guide vanes： A review［J］. Acta Materiae Compositae Sinica， 2023， 40（8）： 4342-4354 （in Chinese）.
3	BHATT R T， SOLA-LOPEZ F， HALBIG M C， et al. Thermal stability of CVI and MI SiC/SiC composites with Hi-Nicalon™-S fibers［J］. Journal of the European Ceramic Society， 2022， 42（8）： 3383-3394.
4	刘巧沐，黄顺洲，何爱杰. 碳化硅陶瓷基复合材料在航空发动机上的应用需求及挑战［J］. 材料工程， 2019， 47（2）： 1-10.
	LIU Q M， HUANG S Z， HE A J. Application requirements and challenges of CMC-SiC composites on aero-engine［J］. Journal of Materials Engineering， 2019， 47（2）： 1-10 （in Chinese）.
5	BUNKER R S. A review of shaped hole turbine film cooling technology［J］. Journal of Heat Transfer， 2005， 127（4）： 441-453.
6	NGUYEN C Q， JOHNSON P L， BERNIER B C， et al. Comparison of film effectiveness and cooling uniformity of conical and cylindrical-shaped film hole with coolant-exit temperature correction‍［J］. Journal of Thermal Science and Engineering Applications， 2011， 3（3）：1897-1907.
7	TASLIM M， UGARTE S. Discharge coefficient measurements for flow through compound-angle conical holes with cross-flow‍［J］. The International Journal of Rotating Machinery， 2004， 10（2）： 145-153.
8	LI C J， LI Y， TONG H， et al. An EDM pulse power generator and its feasible experiments for drilling film cooling holes‍［J］. International Journal of Advanced Manufacturing Technology， 2016， 87（5-8）： 1813-1821.
9	CHEN J， AN Q L， MING W W， et al. Hole exit quality and machined surface integrity of 2D C_f/SiC composites drilled by PCD tools［J］. Journal of the European Ceramic Society， 2019， 39（14）： 4000-4010.
10	FENG P F， WANG J J， ZHANG J F， et al. Drilling induced tearing defects in rotary ultrasonic machining of C/SiC composites［J］. Ceramics International， 2017， 43（1）： 791-799.
11	DING K， FU Y C， SU H H， et al. Experimental studies on drilling tool load and machining quality of C/SiC composites in rotary ultrasonic machining［J］. Journal of Materials Processing Technology， 2014， 214（12）： 2900-2907.
12	HE W B， HE S T， DU J G， et al. Fiber orientations effect on process performance for wire cut electrical discharge machining （WEDM） of 2D C/SiC composite［J］. The International Journal of Advanced Manufacturing Technology， 2019， 102（1-4）： 507-518.
13	杨金华，黄望全，冯晓星，等. 激光类型对 SiC/SiC 复合材料孔加工的影响［J］. 航空材料学报， 2023， 43： 80-86.
	YANG J H， HUANG W Q， FENG X X， et al. Effect of laser type on hole machining of SiC/SiC composites［J］. Journal of Aeronautical Materials， 2023， 43： 80-86 （in Chinese）.
14	WEI J Y， YUAN S M， YANG S， et al. Waterjet-guided laser processing of SiC/SiC ceramic matrix composites to obtain high cleanliness and low oxidation damage characteristics surfaces‍［J］. Surface and Coatings Technology， 2024， 484： 130791.
15	程柏. SiC 纤维增强陶瓷基复合材料的水导激光加工技术研究［D］. 哈尔滨：哈尔滨工业大学， 2022.
	CHENG B. Research on the laser water jet manufacturing technology of silicon carbide fiber reinforced ceramic matrix composites［D］. Harbin： Harbin Institute of Technology， 2022 （in Chinese）.
16	董志刚，杨峰，邢光浩，等. 激光加工SiC_f/SiC陶瓷基复合材料大深径比小孔研究［J］. 复合材料学报， 2025， 42（7）： 3989-4002.
	DONG Z G， YANG F， XING G H， et al. Laser processing of small holes with large aspect ratio in SiC_f/SiC composites［J］. Acta Materiae Compositae Sinica， 2025， 42（7）： 3989-4002 （in Chinese）.
17	SIMA F， SUGIOKA K， VÁZQUEZ R M， et al. Three-dimensional femtosecond laser processing for lab-on-a-chip applications‍［J］. Nanophotonics， 2018， 7（3）： 613-634.
18	PHILLIPS K C， GANDHI H H， MAZUR E， et al. Ultrafast laser processing of materials： a review［J］. Advances in Optics and Photonics， 2015， 7（4）： 684-712.
19	LIU Y S， ZHANG R H， LI W N， et al. Effect of machining parameter on femtosecond laser drilling processing on SiC/SiC composites［J］. The International Journal of Advanced Manufacturing Technology，2018， 96（5-8）： 1795-1811.
20	YANG F， DONG Z G， KANG R K， et al. Femtosecond laser rotary drilling for SiCf/SiC composites［J］. Chinese Journal of Aeronautics， 2025； 38（2）： 103056.
21	GAO L， LIU C， LIU J J， et al. Femtosecond laser drilling of SiC/SiC composites in longitudinal magnetic field and semi-water immersion assistance［J］. Optics & Laser Technology， 2025， 181： 111955.
22	班铭霞，柴兆麟，王曼诗，等. 飞秒激光在镍基合金上加工深宽比>20的直孔和倒锥孔［J］. 中国激光， 2024， 51（18）： 132-140.
	BAN M X， CHAI Z L， WANG M S， et al. Femtosecond laser processing of straight and inverted tapered holes with aspect ratio of >20 on nickel-based alloy［J］. Chinese Journal of Lasers， 2024， 51（18）： 132-140 （in Chinese）.
23	乔亚庆，唐爱国，陈天庭，等. 飞秒激光五轴扫描加工深盲孔［J］. 中国激光， 2023， 50（24）： 201-207.
	QIAO Y Q， TANG A G， CHEN T T， et al. Femtosecond laser five-axis scanning drilling of deep blind holes［J］. Chinese Journal of Lasers， 2023， 50（24）： 201-207 （in Chinese）.
24	HE C， BÜHRING J， GILLNER A. Helical drilling of three-dimensional conical converging-diverging nozzle in steel using ultrashort laser pulses‍［J］. Procedia CIRP， 2018， 74： 305-309.
25	SUN X， DONG X， WANG K， et al. Femtosecond laser processing of controlled tapered micro-holes based on dynamic control of relative attitude‍［J］. Optics & Laser Technology， 2024， 170： 110201.
26	LI M， WEN Z， WANG P， et al. Femtosecond laser high-quality drilling of film cooling holes in nickel-based single superalloy for turbine blades with a two-step helical drilling method‍［J］. Journal of Materials Processing Technology， 2023， 312： 117827.
27	李效基，董一巍，殷春平，等. 飞秒激光螺旋加工小孔几何参数演化实验研究［J］. 中国激光， 2018， 45（5）： 96-105.
	LI X J， DONG Y W， YIN C P， et al. Geometric parameters evolution experiment of hole during femtosecond laser helical drilling［J］. Chinese Journal of Lasers， 2018， 45（5）： 96-105 （in Chinese）.
28	WEI J Y， ZHOU N， GAO M X， et al. Laser ablation of SiC/SiC ceramic matrix composites： Morphological characterization， component evolution and oxidation mechanisms［J］. Corrosion Science， 2024， 227： 111762.
29	MENSINK K， PENILLA E H， MARTÍNEZ-TORRES P， et al. High repetition rate femtosecond laser heat accumulation and ablation thresholds in cobalt-binder and binderless tungsten carbides［J］. Journal of Materials Processing Technology， 2019， 266： 388-396.
30	A Z W， ZOU G S， YU H， et al. Polarization-dependent， beam reflection-regulated hole shaping dynamics visualized by in-situ imaging of ultrafast laser drilling process［J］. Precision Engineering， 2024， 86： 153-159.
31	WANG X， LI L Q， HUANG Y C， et al. Process applicability and hole wall microstructure evolution mechanism of femtosecond laser spiral drilling［J］. Optics & Laser Technology， 2024， 169： 109941.
32	A Z W， ZOU G S， ZHAO W Z， et al. The mechanism of irregular hole-shape formation during ultrafast laser micro-drilling of metals［J］. Applied Physics A， 2023， 129（2）： 120.
33	DUFFT D， ROSENFELD A， DAS S K， et al. Femtosecond laser-induced periodic surface structures revisited： A comparative study on ZnO［J］. Journal of Applied Physics， 2009， 105（3）： 034908.
34	BONSE J， ROSENFELD A， KRÜGER J. On the role of surface plasmon polaritons in the formation of laser-induced periodic surface structures upon irradiation of silicon by femtosecond-laser pulses［J］. Journal of Applied Physics， 2009， 106（10）： 104910.

加工参数	正锥孔		负锥孔
加工参数	底孔	成孔	底孔	成孔
旋转光束半径r/μm	150	150	150	200
激光功率P/W	8	8	12	12
重复频率f/kHz	50	50	50	50
进给速度v/（mm·min^-1）	15	20	20	10
螺距a_p/μm	100	100	100	100

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Femtosecond laser processing method for conical holes in SiC_f/SiC composites

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Femtosecond laser processing method for conical holes in SiC_f/SiC composites