Thermomechanical tool loading and chip formation in oxygen-free titanium cutting

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Benjamin Bergmann
  • Berend Denkena
  • Florian Schaper

Research Organisations

View graph of relations

Details

Original languageEnglish
Pages (from-to)253-259
Number of pages7
JournalCIRP Journal of Manufacturing Science and Technology
Volume45
Early online date21 Jul 2023
Publication statusPublished - Oct 2023

Abstract

Titanium and titanium alloys have high specific strength, excellent corrosion resistance and excellent biocompatibility. Therefore, the use of titanium materials is widespread in high-performance applications such as aerospace and biomedical industries. However, titanium and titanium alloys such as Ti-6Al-4V are considered as difficult to machine. This is attributed to their low thermal conductivity, unfavourable chip formation with typically segmented chips, and high thermomechanical load on the cutting tool. In addition, titanium alloys have a high chemical affinity for surrounding elements such as oxygen. Tool wear, surface and subsurface properties of the workpiece are significantly affected by the presence of oxygen and the resulting chemical interactions. Among other things, chemical reactions such as oxidation occur due to the high temperatures and presence of oxygen. In this work, the chip formation of Ti-6Al-4V at different cutting speeds in continuous orthogonal cutting under different atmospheres is investigated. A conventional air atmosphere, a pure argon atmosphere and a silane-doped argon atmosphere were used. The oxygen content of the silane-doped argon atmosphere corresponds to an extremely high vacuum (XHV), which is practically oxygen-free. It was found that by using an XHV-adequate atmosphere, a significant reduction in chip segmentation occurs. In addition, the feed force is up to 26% lower under silane-doped argon atmosphere compared to cutting under air. This can be attributed to up to 23% reduced coefficient of friction in the secondary shear zone. In addition, the maximum tool temperature at a cutting speed of vc = 60 m/min was reduced by up to 310 °C as a result of using an XHV-adequate atmosphere.

Keywords

    Chip Formation, Cutting, Oxygen, Thermomechanical load, Titanium

ASJC Scopus subject areas

Cite this

Thermomechanical tool loading and chip formation in oxygen-free titanium cutting. / Bergmann, Benjamin; Denkena, Berend; Schaper, Florian.
In: CIRP Journal of Manufacturing Science and Technology, Vol. 45, 10.2023, p. 253-259.

Research output: Contribution to journalArticleResearchpeer review

Bergmann, B, Denkena, B & Schaper, F 2023, 'Thermomechanical tool loading and chip formation in oxygen-free titanium cutting', CIRP Journal of Manufacturing Science and Technology, vol. 45, pp. 253-259. https://doi.org/10.1016/j.cirpj.2023.06.016
Bergmann, B., Denkena, B., & Schaper, F. (2023). Thermomechanical tool loading and chip formation in oxygen-free titanium cutting. CIRP Journal of Manufacturing Science and Technology, 45, 253-259. https://doi.org/10.1016/j.cirpj.2023.06.016
Bergmann B, Denkena B, Schaper F. Thermomechanical tool loading and chip formation in oxygen-free titanium cutting. CIRP Journal of Manufacturing Science and Technology. 2023 Oct;45:253-259. Epub 2023 Jul 21. doi: 10.1016/j.cirpj.2023.06.016
Bergmann, Benjamin ; Denkena, Berend ; Schaper, Florian. / Thermomechanical tool loading and chip formation in oxygen-free titanium cutting. In: CIRP Journal of Manufacturing Science and Technology. 2023 ; Vol. 45. pp. 253-259.
Download
@article{bd1888fb13e944aa84ad3312edf31ce2,
title = "Thermomechanical tool loading and chip formation in oxygen-free titanium cutting",
abstract = "Titanium and titanium alloys have high specific strength, excellent corrosion resistance and excellent biocompatibility. Therefore, the use of titanium materials is widespread in high-performance applications such as aerospace and biomedical industries. However, titanium and titanium alloys such as Ti-6Al-4V are considered as difficult to machine. This is attributed to their low thermal conductivity, unfavourable chip formation with typically segmented chips, and high thermomechanical load on the cutting tool. In addition, titanium alloys have a high chemical affinity for surrounding elements such as oxygen. Tool wear, surface and subsurface properties of the workpiece are significantly affected by the presence of oxygen and the resulting chemical interactions. Among other things, chemical reactions such as oxidation occur due to the high temperatures and presence of oxygen. In this work, the chip formation of Ti-6Al-4V at different cutting speeds in continuous orthogonal cutting under different atmospheres is investigated. A conventional air atmosphere, a pure argon atmosphere and a silane-doped argon atmosphere were used. The oxygen content of the silane-doped argon atmosphere corresponds to an extremely high vacuum (XHV), which is practically oxygen-free. It was found that by using an XHV-adequate atmosphere, a significant reduction in chip segmentation occurs. In addition, the feed force is up to 26% lower under silane-doped argon atmosphere compared to cutting under air. This can be attributed to up to 23% reduced coefficient of friction in the secondary shear zone. In addition, the maximum tool temperature at a cutting speed of vc = 60 m/min was reduced by up to 310 °C as a result of using an XHV-adequate atmosphere.",
keywords = "Chip Formation, Cutting, Oxygen, Thermomechanical load, Titanium",
author = "Benjamin Bergmann and Berend Denkena and Florian Schaper",
note = "Funding Information: The authors appreciate the funding of this work within the Collaborative Research Centre 1368 “Ox-ygen-free Production” by the German Research Foundation (DFG) – Project-ID 394563137 - SFB 1368 . ",
year = "2023",
month = oct,
doi = "10.1016/j.cirpj.2023.06.016",
language = "English",
volume = "45",
pages = "253--259",

}

Download

TY - JOUR

T1 - Thermomechanical tool loading and chip formation in oxygen-free titanium cutting

AU - Bergmann, Benjamin

AU - Denkena, Berend

AU - Schaper, Florian

N1 - Funding Information: The authors appreciate the funding of this work within the Collaborative Research Centre 1368 “Ox-ygen-free Production” by the German Research Foundation (DFG) – Project-ID 394563137 - SFB 1368 .

PY - 2023/10

Y1 - 2023/10

N2 - Titanium and titanium alloys have high specific strength, excellent corrosion resistance and excellent biocompatibility. Therefore, the use of titanium materials is widespread in high-performance applications such as aerospace and biomedical industries. However, titanium and titanium alloys such as Ti-6Al-4V are considered as difficult to machine. This is attributed to their low thermal conductivity, unfavourable chip formation with typically segmented chips, and high thermomechanical load on the cutting tool. In addition, titanium alloys have a high chemical affinity for surrounding elements such as oxygen. Tool wear, surface and subsurface properties of the workpiece are significantly affected by the presence of oxygen and the resulting chemical interactions. Among other things, chemical reactions such as oxidation occur due to the high temperatures and presence of oxygen. In this work, the chip formation of Ti-6Al-4V at different cutting speeds in continuous orthogonal cutting under different atmospheres is investigated. A conventional air atmosphere, a pure argon atmosphere and a silane-doped argon atmosphere were used. The oxygen content of the silane-doped argon atmosphere corresponds to an extremely high vacuum (XHV), which is practically oxygen-free. It was found that by using an XHV-adequate atmosphere, a significant reduction in chip segmentation occurs. In addition, the feed force is up to 26% lower under silane-doped argon atmosphere compared to cutting under air. This can be attributed to up to 23% reduced coefficient of friction in the secondary shear zone. In addition, the maximum tool temperature at a cutting speed of vc = 60 m/min was reduced by up to 310 °C as a result of using an XHV-adequate atmosphere.

AB - Titanium and titanium alloys have high specific strength, excellent corrosion resistance and excellent biocompatibility. Therefore, the use of titanium materials is widespread in high-performance applications such as aerospace and biomedical industries. However, titanium and titanium alloys such as Ti-6Al-4V are considered as difficult to machine. This is attributed to their low thermal conductivity, unfavourable chip formation with typically segmented chips, and high thermomechanical load on the cutting tool. In addition, titanium alloys have a high chemical affinity for surrounding elements such as oxygen. Tool wear, surface and subsurface properties of the workpiece are significantly affected by the presence of oxygen and the resulting chemical interactions. Among other things, chemical reactions such as oxidation occur due to the high temperatures and presence of oxygen. In this work, the chip formation of Ti-6Al-4V at different cutting speeds in continuous orthogonal cutting under different atmospheres is investigated. A conventional air atmosphere, a pure argon atmosphere and a silane-doped argon atmosphere were used. The oxygen content of the silane-doped argon atmosphere corresponds to an extremely high vacuum (XHV), which is practically oxygen-free. It was found that by using an XHV-adequate atmosphere, a significant reduction in chip segmentation occurs. In addition, the feed force is up to 26% lower under silane-doped argon atmosphere compared to cutting under air. This can be attributed to up to 23% reduced coefficient of friction in the secondary shear zone. In addition, the maximum tool temperature at a cutting speed of vc = 60 m/min was reduced by up to 310 °C as a result of using an XHV-adequate atmosphere.

KW - Chip Formation

KW - Cutting

KW - Oxygen

KW - Thermomechanical load

KW - Titanium

UR - http://www.scopus.com/inward/record.url?scp=85165979097&partnerID=8YFLogxK

U2 - 10.1016/j.cirpj.2023.06.016

DO - 10.1016/j.cirpj.2023.06.016

M3 - Article

AN - SCOPUS:85165979097

VL - 45

SP - 253

EP - 259

JO - CIRP Journal of Manufacturing Science and Technology

JF - CIRP Journal of Manufacturing Science and Technology

SN - 1755-5817

ER -