Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions
Inconel 718 is a nickel-based alloy that has been developed with superior mechanical strength, creep resistance, and corrosion, as well as erosion resistance at temperatures above 649 & ring;C. It is suitable to be used for aircraft engine components such as turbine discs. However, it also has l...
Published in: | JURNAL KEJURUTERAAN |
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Language: | Malay |
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UKM PRESS
2024
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Online Access: | https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001331671200027 |
author |
Azhar Muammar Faiq; Haron Che Hassan Che; Ghani Jaharah Abdul; Halim Nurul Hayati Abdul |
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Azhar Muammar Faiq; Haron Che Hassan Che; Ghani Jaharah Abdul; Halim Nurul Hayati Abdul Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions Engineering |
author_facet |
Azhar Muammar Faiq; Haron Che Hassan Che; Ghani Jaharah Abdul; Halim Nurul Hayati Abdul |
author_sort |
Azhar |
spelling |
Azhar, Muammar Faiq; Haron, Che Hassan Che; Ghani, Jaharah Abdul; Halim, Nurul Hayati Abdul Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions JURNAL KEJURUTERAAN Malay Article Inconel 718 is a nickel-based alloy that has been developed with superior mechanical strength, creep resistance, and corrosion, as well as erosion resistance at temperatures above 649 & ring;C. It is suitable to be used for aircraft engine components such as turbine discs. However, it also has low heat conductivity and the presence of hard carbide particles in its alloy worsens the machining conditions with high cutting temperature, and high shear force and promotes work hardening. Thus, this study aims to evaluate the surface integrity of Inconel 718 in terms of surface roughness, plastic deformation, and micro-hardness alterations after the turning process. Cryogenic CO2 cooling was supplied along the cutting process to reduce cutting temperatures and the machining performances were compared with dry machining. The experimental works show that the dry machining resulted in lower surface roughness by up to 42.15% as compared to cryogenic. However, the depth of plastic deformation under dry machining was much more severe than in cryogenic machining driven by higher cutting temperatures and pressure from the worn tool. The depth of plastic deformation became more distinct as the cutting speed increased. While the microhardness alteration of the machined surface was higher under cryogenic machining due to extensive cooling capacity by the CO2 flow. Thus, this study reveals that cryogenic cooling during metal cutting can produce products that have better wear resistance as well as higher surface hardness. UKM PRESS 0128-0198 2289-7526 2024 36 3 Engineering WOS:001331671200027 https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001331671200027 |
title |
Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions |
title_short |
Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions |
title_full |
Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions |
title_fullStr |
Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions |
title_full_unstemmed |
Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions |
title_sort |
Surface Integrity of Inconel 718 under Cryogenic and Dry Cutting Conditions |
container_title |
JURNAL KEJURUTERAAN |
language |
Malay |
format |
Article |
description |
Inconel 718 is a nickel-based alloy that has been developed with superior mechanical strength, creep resistance, and corrosion, as well as erosion resistance at temperatures above 649 & ring;C. It is suitable to be used for aircraft engine components such as turbine discs. However, it also has low heat conductivity and the presence of hard carbide particles in its alloy worsens the machining conditions with high cutting temperature, and high shear force and promotes work hardening. Thus, this study aims to evaluate the surface integrity of Inconel 718 in terms of surface roughness, plastic deformation, and micro-hardness alterations after the turning process. Cryogenic CO2 cooling was supplied along the cutting process to reduce cutting temperatures and the machining performances were compared with dry machining. The experimental works show that the dry machining resulted in lower surface roughness by up to 42.15% as compared to cryogenic. However, the depth of plastic deformation under dry machining was much more severe than in cryogenic machining driven by higher cutting temperatures and pressure from the worn tool. The depth of plastic deformation became more distinct as the cutting speed increased. While the microhardness alteration of the machined surface was higher under cryogenic machining due to extensive cooling capacity by the CO2 flow. Thus, this study reveals that cryogenic cooling during metal cutting can produce products that have better wear resistance as well as higher surface hardness. |
publisher |
UKM PRESS |
issn |
0128-0198 2289-7526 |
publishDate |
2024 |
container_volume |
36 |
container_issue |
3 |
doi_str_mv |
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topic |
Engineering |
topic_facet |
Engineering |
accesstype |
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id |
WOS:001331671200027 |
url |
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001331671200027 |
record_format |
wos |
collection |
Web of Science (WoS) |
_version_ |
1814778544691085312 |