Modeling of the instantaneous subsurface damage mechanism of vibration cutting GH4169 based on strain gradient

Abstract

Nickel-based superalloy GH4169 is widely used in key aircraft engine components due to its excellent thermal strength, stability, and fatigue resistance. However, it is difficult to machine, and ultrasonic vibration cutting is often employed to improve its processability. Sub-surface damage induced during cutting can significantly compromise the fatigue life and reliability of the workpiece. Considering the scale-dependent deformation mechanisms and dislocation behavior in materials, this paper develops an instantaneous sub-surface damage depth prediction model for vibration cutting of nickel-based superalloys based on strain gradient theory. A strain gradient-enhanced constitutive equation for vibration cutting is established with cutting time t as the independent variable. By analyzing real-time cutting force and cutting heat, the coupled effect on sub-surface damage within each vibration cycle is investigated. The von Mises yield criterion is applied, and MATLAB is used to predict instantaneous damage depth. The variation of damage depth with cutting time t is studied, along with its underlying mechanisms. Results show that the maximum instantaneous damage depth occurs when the instantaneous cutting depth peaks. Experimental validation confirms good agreement between predicted and measured damage depths. The key contribution of this work is an instantaneous damage depth prediction model for elliptical vibration machining of GH4169, incorporating strain gradient theory. This model enables the determination of damage depth at different cutting instants, offering insight into damage evolution within each vibration cycle.

Keywords

Nickel-based superalloy GH4169 ultrasonic elliptical vibration cutting strain gradient theory subsurface damage depth

Get full access to this article

View all access options for this article.

References

Bai

Sun

Gao

, et al. (2016) Analysis and modeling of force in orthogonal elliptical vibration cutting. The International Journal of Advanced Manufacturing Technology 83(5-8): 1025–1036.

Dong

(2021) Study on Surface Quality in Ultrasonic Elliptical Vibration Turning of Aviation Aluminum Alloys. Shanghai: Shanghai University of Engineering Science.

Gong

Cai

Gong

, et al. (2023) Grinding subsurface damage mechanism of nickel-based single crystal superalloy based on stress-strain. Precision Engineering-Journal of The International Societies for Precision Engineering and Nanotechnology 86: 1–15.

Han

Zhou

Zou

, et al. (2024) Study on nickel-based single crystal superalloy DD6 subsurface damage of belt grinding with a large cutting depth of one pass. Engineering Failure Analysis 161: 108256.

Hao

Zhang

Fan

(2025) Tool wear mathematical model of PCD during ultrasonic elliptic vibration cutting SiCp/Al composite. International Journal of Refractory Metals and Hard Materials 126: 106967.

Zhang

Xin

, et al. (2024) An experiment study on surface topography of GH4169 assisted by ultrasonic elliptical vibration ultra-precision turning. Applied Sciences-Basel 14(13): 5515.

Huang

Liang

(2003) Modelling of the cutting temperature distribution under the tool flank wear effect. Proc IMechE, Part C: J Mechanical Engineering Science 217: 1195–1208.

Kim

(1995) Theoretical analysis of micro-cutting characteristics in ultra-precision machining. Journal of Materials Processing Technology 49(3-4): 387–398.

Komanduri

Hou

(2000) Thermal modeling of the metal cutting process: part I-temperature rise distribution due to shear plane heat source. International Journal of Mechanical Sciences 42(9): 1715–1752.

10.

Komanduri

Hou

(2001) Thermal modeling of the metal cutting process — part III: temperature rise distribution due to the combined effects of shear plane heat source and the tool-chip interface frictional heat source. International Journal of Mechanical Sciences 43(1): 89–107.

11.

Lazoglu

Ulutan

Alaca

, et al. (2008) An enhanced analytical model for residual stress prediction in machining. Cirp Annals 57(1): 81–84.

12.

Gong

Liu

, et al. (2020) A review on the development of nickel-based superalloys. In: Proceedings of the 14th National Foundry Annual Conference and 2020 China Foundry Week, pp.1–5.

13.

(2020) Research on Cutting Deformation mechanism of Nickel Based High Temperature Alloy GH4169 Based on Strain Gradient Theory. Changchun: Changchun University of Technology.

14.

Liu

Gao

Jiang

, et al. (2020) Analytical modeling of subsurface damage depth in machining of SiCp/Al composites. International Journal of Mechanical Sciences 185: 105874.

15.

Oxley

PLB

Shaw

(1990) Mechanics of machining: an analytical approach to assessing machinability. Journal of Applied Mechanics 57: 253.

16.

Pervaiz

Rashid

Deiab

, et al. (2014) Influence of tool materials on machinability of titanium- and nickel-based alloys: a review. Materials and Manufacturing Processes 29(3): 219–252.

17.

Saif

MTA

Hui

Zehnder

(1993) Interface shear stresses induced by nonuniform heating of a film on a substrate. Thin Solid Films 224(2): 159–167.

18.

Seethaler

Yellowley

(1997) An upper-bound cutting model for oblique cutting tools with a nose radius. International Journal of Machine Tools and Manufacture 37(2): 119–134.

19.

Shamoto

Moriwaki

(1994) Study on elliptical vibration cutting. CIRP Annals 43(1): 35–38.

20.

Smithey

Kapoor

Devor

(2001) A new mechanistic model for predicting worn tool cutting forces. Machining Science and Technology 5(1): 23–42.

21.

Touazine

Chadha

Jahazi

, et al. (2019) Characterization of subsurface microstructural alterations induced by hard turning of Inconel 718. Journal of Materials Engineering and Performance 28(11): 7016–7024.

22.

Usui

Hirota

Masuko

(1978) Analytical predictions of three dimensional cutting process: part 1 basic cutting model and energy approach. Journal of Engineering for Industry 100: 222–228.

23.

Wang

(2019) Modeling, Simulation and Process Optimization of Micro-Milling Burr Based on Strain Gradient Theory. Harbin: Harbin Institute of Technology.

24.

Shan

, et al. (2023) Micromechanical modeling of damage evolution and fracture behavior in particle reinforced metal matrix composites based on the conventional theory of mechanism-based strain gradient plasticity. Journal of Materials Research and Technology 22: 625–641.

25.

Xiao

Wang

, et al. (2012) Study of cutting forces models for micro-cutting based on strain gradient. Key Engineering Materials 499: 307–311.

26.

Xie

Lei

Hua

, et al. (2023) Size and passivation effects in the torsion of thin metallic wires. Acta Mechanica Sinica 39(2): 422346.

27.

Zhang

Yang

Deng

, et al. (2025) Experimental study on surface finish and tool wear in ultrasonic vibration-assisted milling of nickel-based single-crystal superalloys. Precision Engineering-Journal of The International Societies for Precision Engineering and Nanotechnology 94: 571–581.

28.

Zhang

Yuan

Feng

, et al. (2023) Enhanced machinability of Ni-based single crystal superalloy by vibration-assisted diamond cutting. Precision Engineering-Journal of The International Societies for Precision Engineering and Nanotechnology 79: 300–309.

29.

Zhong

Wang

, et al. (2025) Research progress and development trends in nickel-based superalloys. Thermal Processing Technology 10: 1–9.

30.

Zhou

Wang

Chen

, et al. (2023) Study on surface quality and subsurface damage mechanism of nickel-based single-crystal superalloy in precision turning. Journal of Manufacturing Processes 99: 230–242.