Wear map for conventional and nano coated solid carbide end-mill
This work examines the effectiveness of palm oil methyl ester (POME) as lubricant additive and the effect of different combinations of feed rate and depth of cut on the wear of TiAIN coated tools in milling process. Wear map developed for low-speed milling indicates that cracking and fracture can be...
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Universiti Malaysia Sabah
2010
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my.ums.eprints.228352019-07-18T13:52:57Z https://eprints.ums.edu.my/id/eprint/22835/ Wear map for conventional and nano coated solid carbide end-mill Willey Liew Azlan Mohd. Ismail S Agriculture (General) This work examines the effectiveness of palm oil methyl ester (POME) as lubricant additive and the effect of different combinations of feed rate and depth of cut on the wear of TiAIN coated tools in milling process. Wear map developed for low-speed milling indicates that cracking and fracture can be delayed by using the palm oil methly ester as additive in mineral oil, andcombintion of high speed and low feed rate. In milling stavax® with a hardness of 55 HRC under flood condition, three distinct stages of tool wear occurred, (i) initial wear by delamination, attrition and abrasion, followed by (ii) cracking at the substrate and (iii) the formation of individual surface fracture at the cracks which would then enlarge and coalesce to form a large fracture surface. Increasing the feed rate and reducing the speed caused cracking and fracture to take place at a shorter cutting distance. Compare to the flood lubrication, small quantity of mineral oil sprayed in mist form was more effective in reducing the coating delamination and delaying the occurrence of cracking and fracture. The effectiveness of mineral oil in suppressing coating delamination and delaying the occurrence of cracking and fracture could be enhanced by the presence of POME. The mechanism by which the POME suppressed these wear mechanisms could be explained by the results obtained in the four-ball tests which showed that the presence of POME as additive in the mineral oil reduced the friction coefficient, severity of welding of the asperities and wear scar, and increased the critical load for welding to occur. Universiti Malaysia Sabah 2010 Research Report NonPeerReviewed text en https://eprints.ums.edu.my/id/eprint/22835/1/Wear%20map%20for%20conventional%20and%20nano%20coated%20solid%20carbide%20end-mill.pdf Willey Liew and Azlan Mohd. Ismail (2010) Wear map for conventional and nano coated solid carbide end-mill. (Unpublished) |
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S Agriculture (General) Willey Liew Azlan Mohd. Ismail Wear map for conventional and nano coated solid carbide end-mill |
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This work examines the effectiveness of palm oil methyl ester (POME) as lubricant additive and the effect of different combinations of feed rate and depth of cut on the wear of TiAIN coated tools in milling process. Wear map developed for low-speed milling indicates that cracking and fracture can be delayed by using the palm oil methly ester as additive in
mineral oil, andcombintion of high speed and low feed rate. In milling stavax® with a hardness of 55 HRC under flood condition, three distinct stages of tool wear occurred, (i)
initial wear by delamination, attrition and abrasion, followed by (ii) cracking at the substrate and (iii) the formation of individual surface fracture at the cracks which would then enlarge and coalesce to form a large fracture surface. Increasing the feed rate and reducing the speed caused cracking and fracture to take place at a shorter cutting distance. Compare to the flood lubrication, small quantity of mineral oil sprayed in mist form was
more effective in reducing the coating delamination and delaying the occurrence of cracking
and fracture. The effectiveness of mineral oil in suppressing coating delamination and
delaying the occurrence of cracking and fracture could be enhanced by the presence of
POME. The mechanism by which the POME suppressed these wear mechanisms could be
explained by the results obtained in the four-ball tests which showed that the presence of
POME as additive in the mineral oil reduced the friction coefficient, severity of welding of
the asperities and wear scar, and increased the critical load for welding to occur. |
| format |
Research Report |
| author |
Willey Liew Azlan Mohd. Ismail |
| author_facet |
Willey Liew Azlan Mohd. Ismail |
| author_sort |
Willey Liew |
| title |
Wear map for conventional and nano coated solid carbide end-mill |
| title_short |
Wear map for conventional and nano coated solid carbide end-mill |
| title_full |
Wear map for conventional and nano coated solid carbide end-mill |
| title_fullStr |
Wear map for conventional and nano coated solid carbide end-mill |
| title_full_unstemmed |
Wear map for conventional and nano coated solid carbide end-mill |
| title_sort |
wear map for conventional and nano coated solid carbide end-mill |
| publisher |
Universiti Malaysia Sabah |
| publishDate |
2010 |
| url |
https://eprints.ums.edu.my/id/eprint/22835/1/Wear%20map%20for%20conventional%20and%20nano%20coated%20solid%20carbide%20end-mill.pdf https://eprints.ums.edu.my/id/eprint/22835/ |
| _version_ |
1760230023075201024 |
| score |
13.211869 |