Sage Journals: Discover world-class research

Abstract

Nickel-based superalloys are widely utilized in the production of aviation and gas turbine hot end components due to their excellent mechanical properties. However, their poor machinability and low processing efficiency have hindered their further development in aerospace. SiAlON ceramic tools present superior cutting performance when machining nickel-based superalloys. Firstly, the service lives of circular ceramic cutting tools and diamond-shaped ceramic cutting tools were compared. Studies have shown that circular SiAlON ceramic cutting tools exhibit a longer service life when machining nickel-based superalloys. Additionally, the variation laws of cutting temperature, machined surface quality, wear mechanism, and machine tool current of circular ceramic cutting tools under different cutting speeds (100–250 m/min) were systematically measured and studied. By analyzing the maximum flank wear amount, the optimal cutting parameters were determined as follows: cutting speed v_c = 100 m/min, feed rate f_r = 0.1 mm/r, and cutting depth a_p = 0.1 mm. Experimental results show that among the three ceramic tools, the 6160 (R) consumes the least machine tool current, while the CS100 (R) consumes the most. Moreover, the cutting speed has a significant impact on the machine tool current, whereas the cutting depth and feed rate have a relatively smaller impact. The wear forms and wear mechanisms of the ceramic tools were analyzed using SEM and EDS. Results show that abrasive wear is dominant under low-speed conditions (100 and 150 m/min), and adhesion and diffusion wear increase significantly with the rise of cutting speeds (above 150 m/min). This study offers a foundation for cutting tool selection in high-efficiency machining of GH4169.

Keywords

nickel-based superalloy SiAlON ceramic tools cutting performance wear mechanism machine tool current

Get full access to this article

View all access options for this article.

References

Akande

Oluwole

Fayomi

OSI

, et al. Overview of mechanical, microstructural, oxidation properties and high-temperature applications of superalloys. Mater Today Proc 2021; 43: 2222–2231.

Zhang

Zhuang

, et al. Hot corrosion and mechanical performance of repaired Inconel 718 components via laser additive manufacturing. Materials 2020; 13(9): 2128.

Fan

Wang

, et al. A review on cutting tool technology in machining of Ni-based superalloys. Int J Adv Manuf Technol 2020; 110: 2863–2879.

Yuan

Zhao

Wei

, et al. Impact of post-heat treatment on the mechanical and tribological properties of GH4169/V coatings produced by laser cladding. Wear 2025; 571: 205829.

Elgazzar

Zhou

Ouyang

, et al. A critical review of high-temperature tribology and cutting performance of cermet and ceramic tool materials. Lubricants 2023; 11(3): 122.

Ishfaq

Anjum

Pruncu

, et al. Progressing towards sustainable machining of steels: a detailed review. Materials 2021; 14(18): 5162.

Grigoriev

Fedorov

Hamdy

Materials, properties, manufacturing methods and cutting performance of innovative ceramic cutting tools − a review. Manuf Rev 2019; 6: 19.

Wang

Jin

Zhao

, et al. A comparative study on tool life and wear of uncoated and coated cutting tools in turning of tungsten heavy alloys. Wear 2021; 482–483: 203929.

Altin

Nalbant

Taskesen

The effects of cutting speed on tool wear and tool life when machining Inconel 718 with ceramic tools. Mater Des 2007; 28: 2518–2522.

10.

Yin

Yan

, et al. Cutting performance of microwave-sintered sub-crystal Al₂O₃/SiC ceramic tool in dry cutting of hardened steel. Ceram Int 2019; 45(13): 16113–16120.

11.

Tan

Liu

Zhou

, et al. Improvement of cutting performance of SiAlON ceramic by texture engineering in turning superalloys. Ceram Int 2023; 49(18): 29971–29983.

12.

Lü

Deng

Tian

, et al. Cutting performance of Si₃N₄/TiC micro-nanocomposite ceramic tool in dry machining of hardened steel. Int J Adv Manuf Technol 2018; 95: 3301–3307.

13.

Duan

Wang

Xing

Investigation of novel multiscale textures for the enhancement of the cutting performance of Al₂O₃/TiC ceramic cutting tools. Ceram Int 2022; 48(3): 3554–3563.

14.

Ming

, et al. Wear behavior of SiAlON ceramic tool and its effects during high-speed cutting. Ceram Int 2023; 49(16): 26694–26706.

15.

Akincioğlu

Gökkaya

Akincioğlu

, et al. Taguchi optimization of surface roughness in the turning of Hastelloy C22 super alloy using cryogenically treated ceramic inserts. Proc IMechE Part C: J Mechanical Engineering Science 2020; 234: 3826–3836.

16.

Ming

, et al. Wear and failure mechanisms of SiAlON ceramic tools during high-speed turning of nickel-based superalloys. Wear 2022; 488-489: 204171.

17.

Cui

Zhao

Wang

, et al. Cutting performance, failure mechanisms and tribological properties of GNPs reinforced Al2O3/Ti(C,N) ceramic tool in high speed turning of Inconel 718. Ceram Int 2020; 46(11): 18859–18867.

18.

Zhuang

Zhu

Zhang

, et al. Notch wear prediction model in turning of Inconel 718 with ceramic tools considering the influence of work hardened layer. Wear 2014; 313(1–2): 63–74.

19.

Wang

Zhao

Gan

, et al. Cutting performance and wear mechanisms of the graphene-reinforced Al₂O₃-WC-TiC composite ceramic tool in turning hardened 40Cr steel. Ceram Int 2022; 48(10): 13695–13705.

20.

Lin

Lai

, et al. Wear mechanism and tool life prediction of high-strength vermicular graphite cast iron tools for high-efficiency cutting. Wear 2020; 454-455: 203319.

21.

Pozzato

Bertolini

Moro

, et al. On the wear mechanisms of ceramic round inserts in high-speed turning of Inconel 718. Wear 2025; 571: 205866.

22.

Kyocera comprehensive sample of cutting tools. https://www.kyocera.com.cn/prdct/cuttingtool/sample/category/1 (2000, accessed 10 June 2025).

23.

Seco turning samples. https://www.secotools.com/article/84585 (1996, accessed 10 June 2025).

24.

Prasad

NE.

Aerospace materials and material technologies. Springer, 2017. p.199.

25.

Kuntoğlu

Aslan

Pimenov

, et al. A review of indirect tool condition monitoring systems and decision-making methods in turning: Critical analysis and trends. Sensors 2020; 21(1): 108.

26.

Liu

Zhang

, et al. Wear patterns and mechanisms of cutting tools in high-speed face milling. J Mater Process Technol 2002; 129(1-3): 222–226.

27.

Zhao

Wang

Huang

, et al. Micro ultrasonic machining hemispherical mold for MEMS resonator gyroscope using a novel ultraprecise ceramic entire-ball tool. J Micromech Microeng 2020; 30: 075007.

28.

Zhao

Huang

Xiang

, et al. Effect of a protective coating on the surface integrity of a microchannel produced by microultrasonic machining. J Manuf Process 2021; 61: 280–295.

29.

Pervaiz

Kannan

Deiab

, et al. Role of energy consumption, cutting tool and workpiece materials towards environmentally conscious machining: a comprehensive review. Proc. IMechE, Part B: J. Eng. Manuf 2020; 234(3): 335–354.

Cutting performance and wear mechanisms of SiAlON ceramic tools in high-speed turning of GH4169

Abstract

Keywords

Get full access to this article

References