Machining performance and wear behaviour of polycrystalline diamond and coated carbide tools during milling of titanium alloy Ti-54M
(2023) In Wear 523.- Abstract
Polycrystalline diamond (PCD) is currently under development as a new generation of cutting tool material for titanium alloy machining applications. The unrivaled high temperature hardness possessed by PCD offers the potential for higher levels of productivity compared to tungsten carbide, the current industry standard tool material, through facilitating higher cutting speeds. This study investigates the performance of various PCD tool grades during square shoulder milling of Ti-54M. The influence of PCD grain size on dominant wear mechanism has been established, revealing that a smaller, sub 1 μm, grain size offers improvements in tool life due to superior fracture toughness compared to larger grained material. For fine grained PCD,... (More)
Polycrystalline diamond (PCD) is currently under development as a new generation of cutting tool material for titanium alloy machining applications. The unrivaled high temperature hardness possessed by PCD offers the potential for higher levels of productivity compared to tungsten carbide, the current industry standard tool material, through facilitating higher cutting speeds. This study investigates the performance of various PCD tool grades during square shoulder milling of Ti-54M. The influence of PCD grain size on dominant wear mechanism has been established, revealing that a smaller, sub 1 μm, grain size offers improvements in tool life due to superior fracture toughness compared to larger grained material. For fine grained PCD, loss of tool material through a cyclic process of workpiece adhesion followed by grain pull-out was identified to be the predominant wear mechanism, contrasting the mechanical fracture dominated wear observed for the larger grained PCD grades. The influence of insert microgeometry was also investigated through honing of the cutting edge radii. An increased tendency for edge fracture was demonstrated when machining with larger radii tooling which was attributed to increased cutting forces. Finally, the study has compared the surface integrity response of the workpiece following PCD and carbide machining, revealing considerably lower levels of microstructural damage and cutting forces when machining with PCD. This highlights the potential benefits of PCD in finishing applications, whereby high speed machining can be employed to reduce the impact on component surface integrity.
(Less)
- author
- Childerhouse, Thomas ; M'Saoubi, Rachid LU ; Franca, Luiz F.P. ; Crawforth, Pete and Jackson, Martin
- organization
- publishing date
- 2023
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- Advanced cutting tool materials, High speed machining, Surface integrity, Titanium alloys, Tool wear
- in
- Wear
- volume
- 523
- article number
- 204791
- publisher
- Elsevier
- external identifiers
-
- scopus:85151347209
- ISSN
- 0043-1648
- DOI
- 10.1016/j.wear.2023.204791
- language
- English
- LU publication?
- yes
- id
- 5e8fca2a-fdd9-4750-906f-65810608c421
- date added to LUP
- 2023-05-24 13:03:30
- date last changed
- 2023-05-24 13:03:30
@article{5e8fca2a-fdd9-4750-906f-65810608c421,
abstract = {{<p>Polycrystalline diamond (PCD) is currently under development as a new generation of cutting tool material for titanium alloy machining applications. The unrivaled high temperature hardness possessed by PCD offers the potential for higher levels of productivity compared to tungsten carbide, the current industry standard tool material, through facilitating higher cutting speeds. This study investigates the performance of various PCD tool grades during square shoulder milling of Ti-54M. The influence of PCD grain size on dominant wear mechanism has been established, revealing that a smaller, sub 1 μm, grain size offers improvements in tool life due to superior fracture toughness compared to larger grained material. For fine grained PCD, loss of tool material through a cyclic process of workpiece adhesion followed by grain pull-out was identified to be the predominant wear mechanism, contrasting the mechanical fracture dominated wear observed for the larger grained PCD grades. The influence of insert microgeometry was also investigated through honing of the cutting edge radii. An increased tendency for edge fracture was demonstrated when machining with larger radii tooling which was attributed to increased cutting forces. Finally, the study has compared the surface integrity response of the workpiece following PCD and carbide machining, revealing considerably lower levels of microstructural damage and cutting forces when machining with PCD. This highlights the potential benefits of PCD in finishing applications, whereby high speed machining can be employed to reduce the impact on component surface integrity.</p>}},
author = {{Childerhouse, Thomas and M'Saoubi, Rachid and Franca, Luiz F.P. and Crawforth, Pete and Jackson, Martin}},
issn = {{0043-1648}},
keywords = {{Advanced cutting tool materials; High speed machining; Surface integrity; Titanium alloys; Tool wear}},
language = {{eng}},
publisher = {{Elsevier}},
series = {{Wear}},
title = {{Machining performance and wear behaviour of polycrystalline diamond and coated carbide tools during milling of titanium alloy Ti-54M}},
url = {{http://dx.doi.org/10.1016/j.wear.2023.204791}},
doi = {{10.1016/j.wear.2023.204791}},
volume = {{523}},
year = {{2023}},
}