Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process

Orthogonal metal cutting process involves large plastic deformation accompanied by excessive heat generation. This work addresses the thermal-mechanical responses of the workpiece material at the tool-workpiece contact. In this respect, the orthogonal cutting process of Ti-6Al-4V using CVD diamond t...

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Main Authors: Tamin, M. N., Sudin, I., Mon, T. T.
Format: Article
Published: 2008
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Online Access:http://eprints.utm.my/id/eprint/5406/
http://dx.doi.org/10.4028/www.scientific.net/DDF.273-276.673
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spelling my.utm.54062017-10-09T05:38:45Z http://eprints.utm.my/id/eprint/5406/ Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process Tamin, M. N. Sudin, I. Mon, T. T. TJ Mechanical engineering and machinery Orthogonal metal cutting process involves large plastic deformation accompanied by excessive heat generation. This work addresses the thermal-mechanical responses of the workpiece material at the tool-workpiece contact. In this respect, the orthogonal cutting process of Ti-6Al-4V using CVD diamond tool is simulated using finite element method. The cutting condition consists of cutting speed, K=180 m/min, feed rate, t=0.125 mm/rev and width of cut of 1.25 mm. Eulerian formulation with coupled thermal-mechanical analysis is employed in the model. The JohnsonCook constitutive equation is employed for Ti-6Al-4V workpiece material to accurately simulate the formation of shear bands. The stick-slip friction condition is modeled at the tool-chip interface. The sliding coefficient of friction of 0.8 and the limiting shear stress of 700 MPa for stick-slip condition are determined experimentally. Results show that high temperature and temperature gradient concentrate in the primary shear zone and the contact area between the tool rake face and the chip. A primary shear band is predicted in the workpiece ahead of the tool-workpiece contact face while the secondary shear band is formed in the chip. This highly-deformed shear band is revealed in the microstructure of etched chips. The predicted high strain rate results in build-up edge at tool cutting edge-chip contact. Low cutting condition of V=150 m/min, t=0.125 mm/rev promotes stagnant zone formation that helps preserve the cutting edge of the tool. The maximum predicted temperature at the cutting edge is in excess of 700°C Such high temperature level facilitates diffusion of carbon elements into the chips and conversely, elements of titanium into the CVD diamond tool. 2008 Article PeerReviewed Tamin, M. N. and Sudin, I. and Mon, T. T. (2008) Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process. Diffusion and Defect Data. Pt A Defect and Diffusion Forum, 273-276 . pp. 673-678. ISSN 1012-0386 http://dx.doi.org/10.4028/www.scientific.net/DDF.273-276.673
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic TJ Mechanical engineering and machinery
spellingShingle TJ Mechanical engineering and machinery
Tamin, M. N.
Sudin, I.
Mon, T. T.
Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process
description Orthogonal metal cutting process involves large plastic deformation accompanied by excessive heat generation. This work addresses the thermal-mechanical responses of the workpiece material at the tool-workpiece contact. In this respect, the orthogonal cutting process of Ti-6Al-4V using CVD diamond tool is simulated using finite element method. The cutting condition consists of cutting speed, K=180 m/min, feed rate, t=0.125 mm/rev and width of cut of 1.25 mm. Eulerian formulation with coupled thermal-mechanical analysis is employed in the model. The JohnsonCook constitutive equation is employed for Ti-6Al-4V workpiece material to accurately simulate the formation of shear bands. The stick-slip friction condition is modeled at the tool-chip interface. The sliding coefficient of friction of 0.8 and the limiting shear stress of 700 MPa for stick-slip condition are determined experimentally. Results show that high temperature and temperature gradient concentrate in the primary shear zone and the contact area between the tool rake face and the chip. A primary shear band is predicted in the workpiece ahead of the tool-workpiece contact face while the secondary shear band is formed in the chip. This highly-deformed shear band is revealed in the microstructure of etched chips. The predicted high strain rate results in build-up edge at tool cutting edge-chip contact. Low cutting condition of V=150 m/min, t=0.125 mm/rev promotes stagnant zone formation that helps preserve the cutting edge of the tool. The maximum predicted temperature at the cutting edge is in excess of 700°C Such high temperature level facilitates diffusion of carbon elements into the chips and conversely, elements of titanium into the CVD diamond tool.
format Article
author Tamin, M. N.
Sudin, I.
Mon, T. T.
author_facet Tamin, M. N.
Sudin, I.
Mon, T. T.
author_sort Tamin, M. N.
title Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process
title_short Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process
title_full Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process
title_fullStr Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process
title_full_unstemmed Thermal-mechanical responses of Ti-6Al-4V during orthogonal cutting process
title_sort thermal-mechanical responses of ti-6al-4v during orthogonal cutting process
publishDate 2008
url http://eprints.utm.my/id/eprint/5406/
http://dx.doi.org/10.4028/www.scientific.net/DDF.273-276.673
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score 13.214268