Influence of turning tool wear on the surface integrity and anti-fatigue behavior of Ti1023

Titanium alloy Ti1023 is a typical difficult-to-cut material. Tool wear is easy to occur in machining Ti1023, which has a significant negative effect on surface integrity. Turning is one of the common methods to machine Ti1023 parts and machined surface integrity has a direct influence on the fatigu...

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Bibliographic Details
Published inAdvances in mechanical engineering Vol. 13; no. 4
Main Authors Xun, Li, Ziming, Wang, Shenliang, Yang, Zhiyuan, Guo, Yongxin, Zhou, Kangning, Han
Format Journal Article
LanguageEnglish
Published London, England SAGE Publications 01.04.2021
Sage Publications Ltd
SAGE Publishing
Subjects
Aluminum
Control surfaces
Deformation wear
Fatigue life
Fatigue tests
Heat treating
Integrity
Low cycle fatigue
Microhardness
Plastic deformation
Residual stress
Surface defects
Surface roughness
Titanium alloys
Titanium base alloys
Tool wear
Turning (machining)
Workpieces
Titanium alloy
tool wear
surface integrity
anti-fatigue behavior
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Summary:Titanium alloy Ti1023 is a typical difficult-to-cut material. Tool wear is easy to occur in machining Ti1023, which has a significant negative effect on surface integrity. Turning is one of the common methods to machine Ti1023 parts and machined surface integrity has a direct influence on the fatigue life of parts. To control surface integrity and improve anti-fatigue behavior of Ti1023 parts, it has an important significance to study the influence of tool wear on the surface integrity and fatigue life of Ti1023 in turning. Therefore, the effect of tool wear on the surface roughness, microhardness, residual stress, and plastic deformation layer of Ti1023 workpieces by turning and low-cycle fatigue tests were studied. Meanwhile, the influence mechanism of surface integrity on anti-fatigue behavior also was analyzed. The experimental results show that the change of surface roughness caused by worn tools has the most influence on anti-fatigue behavior when the tool wear VB is from 0.05 to 0.25 mm. On the other hand, the plastic deformation layer on the machined surface could properly improve the anti-fatigue behavior of specimens that were proved in the experiments. However, the higher surface roughness and significant surface defects on surface machined utilizing the worn tool with VB = 0.30 mm, which leads the anti-fatigue behavior of specimens to decrease sharply. Therefore, to ensure the anti-fatigue behavior of parts, the value of turning tool wear VB must be rigorously controlled under 0.30 mm during finishing machining of titanium alloy Ti1023.
ISSN:1687-8132
1687-8140
DOI:10.1177/16878140211011278