Sage Journals: Discover world-class research

Abstract

The water chamber head is a critical component of nuclear power equipment, manufactured from 508III steel. During the milling process, the tool is subjected to high mechanical impact and cutting temperatures, making it highly susceptible to severe wear and breakage. If tool failure is not identified and the tool is not replaced promptly, it will lead to cutting anomalies. Chip morphology is closely related to tool condition and therefore serves as an important basis for identifying tool condition. By analyzing the influence of tool condition on chip morphology, this can provide the theoretical basis and technical support for tool condition identification based on chip morphology. Firstly, a milling experiment was conducted on 508III steel to collect chip samples at different stages of wear and breakage, and the changing law of chip morphology was analyzed. Secondly, the cutting tool’s wear and breakage were observed, and the formation of chips and the causes of curling deformation were discussed. Furthermore, the changes in chip morphology after edge wear, groove wear, and fatigue breakage of the cutting tool are discussed. Edge wear affects the degree of upward curling of the chip, whereas groove wear and breakage primarily affect the degree of lateral curling of the chip. Finally, finite element simulations of chip morphology under no tool wear, edge wear, and groove wear are performed to confirm the changes in chip morphology.

Keywords

508III steel tool wear and breakage chip morphology finite element simulation

Get full access to this article

View all access options for this article.

References

Liu

Cheng

Guan

, et al. Performance evaluation of coated cemented carbide inserts milling 508III steel. Int J Nanomanuf 2018; 14(2): 101–114.

Liu

Zhang

, et al. An approach for tool wear prediction using customized DenseNet and GRU integrated model based on multi-sensor feature fusion. J Intell Manuf 2022; 34(2): 885–902.

Mikhailov

Kovelenov

Bolotskikh

SV.

Simulation of chip formation and fracture in the design of complex turning inserts. Russian Eng Res 2018; 38(7): 566–572.

Shen

Research on tool wear of high-speed milling 300M ultra-high-strength steel. Shaanxi University of Science and Technology, 2020.

Fan

Zhang

Chen

, et al. Analysis of tool wear of TiAlN coated tool, machined surface morphology, and chip during titanium alloy milling. Tribol Int 2024; 197: 109751.

Guan

Cheng

Xue

, et al. Analysis of chip morphology in heavy milling of 508III steel considering different tool wear conditions. Materials 2024; 17(16): 3948.

Pérez-Salinas

de Lacalle

LNL

del Olmo

, et al. The relationship between the cutting-edge, tool wear, and chip formation during Inconel 718 dry cutting. Int J Adv Manuf Technol 2024; 132(11–12): 6001–6017.

Dargusch

Sun

Kim

, et al. Effect of tool wear evolution on chip formation during dry machining of Ti-6Al-4V alloy. Int J Mach Tools Manuf 2018; 126: 13–17.

Gdula

Mrówka-Nowotnik

Analysis of tool wear, chip and machined surface morphology in multi-axis milling process of Ni-based superalloy using the torus milling cutter. Wear 2023; 520–521: 204652.

10.

Halim

NHA

Haron

CHC

Ghani

, et al. Tool wear and chip morphology in high-speed milling of hardened Inconel 718 under dry and cryogenic CO₂ conditions. Wear 2019; 426–427: 1683–1690.

11.

Tong

Liu

Gao

, et al. Formation mechanism and morphology observation of chips in high-speed milling of titanium alloy. J Adv Manuf Syst 2024; 23(3): 549–575.

12.

Zhu

Cai

Qian

XH.

Influence of different cutting edges caused by tool wear on cutting process of titanium alloy TC21 based on finite element model. Proc Inst Mech Eng Part B: J Eng Manuf 2023; 237(1–2): 229–239.

13.

Rajput

Upadhyay

Gangopadhyay

, et al. Effects of roughing, finishing, and aggressive machining conditions on the milling performance of AISI 1045 steel using TiAlN coated inserts. Proc Inst Mech Eng Part B: J Eng Manuf 2025; 239(3): 376–387.

14.

Cheng

Ding

Guan

, et al. Simulation and experimental study of tool wear and damage in milling SA 508III steel. Surf Topogr 2022; 10(3): 035033.

15.

XB.

Research on intelligent monitoring technology for tool wear and breakage during milling processes. Harbin University of Science and Technology, 2023.

16.

Chen

Zhao

Liu

, et al. Investigation on the chip formation concerning tool inclination angles in ball end milling of H13 die steel. Proc Inst Mech Eng Part B: J Eng Manuf 2014; 228(3): 337–355.

Analysis of the effect of tool wear and breakage in milling 508III steel on chip morphology

Abstract

Keywords

Get full access to this article

References