Quantification of plastic deformation in hardmetal tool inserts at the macroscopic and microstructural level

Tong, V.; Jones, C.; Roebuck, B.; Walsh, M.; Alm, P.; Olovsjö, S.; M'Saoubi, R.; Mingard, K.

Quantification of plastic deformation in hardmetal tool inserts at the macroscopic and microstructural level

Mark

Tong, V. ; Jones, C. ; Roebuck, B. ; Walsh, M. ; Alm, P. ^LU ; Olovsjö, S. ; M'Saoubi, R. ^LU and Mingard, K. (2026) In International Journal of Refractory Metals and Hard Materials 139.

Abstract: AbstractThe need to minimise wear of hardmetal cutting tool materials requires an understanding of, and in turn accurate measurement of, both the external changes in dimensions and the internal microstructural changes which cause plastic deformation underneath the tool coating.This paper summarises development of methods to quantify the dimensional changes of the complex 3D tip shape of a tool and, from the same tool, quantify the plastic deformation characteristics of the underlying microstructure that determine the external 3D change of shape.Dimensional changes of the tip shape have been measured using a 3D optical microscope to quantify the small, micrometre scale changes of the worn tip relative to the no-longer-present original... (More); AbstractThe need to minimise wear of hardmetal cutting tool materials requires an understanding of, and in turn accurate measurement of, both the external changes in dimensions and the internal microstructural changes which cause plastic deformation underneath the tool coating.This paper summarises development of methods to quantify the dimensional changes of the complex 3D tip shape of a tool and, from the same tool, quantify the plastic deformation characteristics of the underlying microstructure that determine the external 3D change of shape.Dimensional changes of the tip shape have been measured using a 3D optical microscope to quantify the small, micrometre scale changes of the worn tip relative to the no-longer-present original surface. The tips have then been sectioned on a well-defined plane relative to the cutting force and the microstructure mapped over large areas at high resolution. Methods to quantify the defects produced by the high temperature creep processes have been evaluated and compared with the external shape change and fundamental creep properties of the hardmetal grades used.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/599f2114-bb3a-4193-a305-980c5258ab85

author

Tong, V. ; Jones, C. ; Roebuck, B. ; Walsh, M. ; Alm, P. ^LU ; Olovsjö, S. ; M'Saoubi, R. ^LU and Mingard, K.

organization

publishing date

2026-09

type

Contribution to journal

publication status

published

subject

keywords

3D microscopy, Cemented carbides, High-temperature creep testing, Plastic deformation, Scanning electron microscopy, Turning insert wear

in

International Journal of Refractory Metals and Hard Materials

volume

139

article number

107770

publisher

Elsevier

external identifiers

scopus:105034613967

ISSN

0263-4368

DOI

10.1016/j.ijrmhm.2026.107770

language

English

LU publication?

yes

additional info

id

599f2114-bb3a-4193-a305-980c5258ab85

date added to LUP

2026-05-27 14:02:13

date last changed

2026-05-27 14:02:54

@article{599f2114-bb3a-4193-a305-980c5258ab85,
  abstract     = {{<p>AbstractThe need to minimise wear of hardmetal cutting tool materials requires an understanding of, and in turn accurate measurement of, both the external changes in dimensions and the internal microstructural changes which cause plastic deformation underneath the tool coating.This paper summarises development of methods to quantify the dimensional changes of the complex 3D tip shape of a tool and, from the same tool, quantify the plastic deformation characteristics of the underlying microstructure that determine the external 3D change of shape.Dimensional changes of the tip shape have been measured using a 3D optical microscope to quantify the small, micrometre scale changes of the worn tip relative to the no-longer-present original surface. The tips have then been sectioned on a well-defined plane relative to the cutting force and the microstructure mapped over large areas at high resolution. Methods to quantify the defects produced by the high temperature creep processes have been evaluated and compared with the external shape change and fundamental creep properties of the hardmetal grades used.</p>}},
  author       = {{Tong, V. and Jones, C. and Roebuck, B. and Walsh, M. and Alm, P. and Olovsjö, S. and M'Saoubi, R. and Mingard, K.}},
  issn         = {{0263-4368}},
  keywords     = {{3D microscopy; Cemented carbides; High-temperature creep testing; Plastic deformation; Scanning electron microscopy; Turning insert wear}},
  language     = {{eng}},
  publisher    = {{Elsevier}},
  series       = {{International Journal of Refractory Metals and Hard Materials}},
  title        = {{Quantification of plastic deformation in hardmetal tool inserts at the macroscopic and microstructural level}},
  url          = {{http://dx.doi.org/10.1016/j.ijrmhm.2026.107770}},
  doi          = {{10.1016/j.ijrmhm.2026.107770}},
  volume       = {{139}},
  year         = {{2026}},
}

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Quantification of plastic deformation in hardmetal tool inserts at the macroscopic and microstructural level