Indentation Plastometry for Study of Anisotropy and Inhomogeneity in Maraging Steel Produced by Laser Powder Bed Fusion

Tom Southern; Jimmy E. Campbell; Kyriakos I. Kourousis; Barry Mooney; Yuanbo T. Tang; Trevor William Clyne

doi:10.1002/srin.202200881

Indentation Plastometry for Study of Anisotropy and Inhomogeneity in Maraging Steel Produced by Laser Powder Bed Fusion

Tom Southern, Jimmy E. Campbell, Kyriakos I. Kourousis, Barry Mooney, Yuanbo T. Tang, Trevor William Clyne^*

^*Corresponding author for this work

Metallurgy and Materials

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Abstract

This work concerns the use of profilometry-based indentation plastometry (PIP) to obtain mechanical property information for maraging steel samples produced via an additive manufacturing route (laser powder bed fusion). Bars are produced in both “horizontal” (all material close to the build plate) and “vertical” (progressively increasing distance from the build plate) configurations. Samples are mechanically tested in both as-built and age-hardened conditions. Stress–strain curves from uniaxial testing (tensile and compressive) are compared with those from PIP testing. Tensile test data suggest significant anisotropy, with the horizontal direction harder than the vertical direction. However, systematic compressive tests, allowing curves to be obtained for both build and transverse directions in various locations, indicate that there is no anisotropy anywhere in these materials. This is consistent with electron backscattered diffraction results, indicating that there is no significant texture in these materials. It is also consistent with the outcomes of PIP testing, which can detect anisotropy with high sensitivity. Furthermore, both PIP testing and compression testing results indicate that the changing growth conditions at different distances from the build plate can lead to strength variations. It seems likely that what has previously been interpreted as anisotropy in the tensile response is in fact due to inhomogeneity of this type.

Original language	English
Article number	2200881
Number of pages	10
Journal	Steel Research International
Volume	94
Issue number	7
Early online date	9 Mar 2023
DOIs	https://doi.org/10.1002/srin.202200881
Publication status	Published - Jul 2023

Bibliographical note

Acknowledgments:
Relevant support for TWC has been received from EPSRC (grant EP/I038691/1) and from the Leverhulme Trust, in the form of an International Network grant (IN-2016-004) and an Emeritus Fellowship (EM/2019-038/4). In addition, an ongoing Innovate UK grant (project number 10006185) covers work in this area and JEC is in receipt of a Future Leaders grant from Innovate UK (MR/W01338X/1), which is focused on development of the PIP technique. Financial support has also been received (for KIK and BM) from the Irish Research Council (IRC), through the Government of Ireland Postgraduate Research Programme (grant ID: GOIPG/2017/1041) and from the Faculty of Science and Engineering of the University of Limerick.

Keywords

anisotropy
indentation plastometry
laser packed bed fusion
maraging steels

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title = "Indentation Plastometry for Study of Anisotropy and Inhomogeneity in Maraging Steel Produced by Laser Powder Bed Fusion",

abstract = "This work concerns the use of profilometry-based indentation plastometry (PIP) to obtain mechanical property information for maraging steel samples produced via an additive manufacturing route (laser powder bed fusion). Bars are produced in both “horizontal” (all material close to the build plate) and “vertical” (progressively increasing distance from the build plate) configurations. Samples are mechanically tested in both as-built and age-hardened conditions. Stress–strain curves from uniaxial testing (tensile and compressive) are compared with those from PIP testing. Tensile test data suggest significant anisotropy, with the horizontal direction harder than the vertical direction. However, systematic compressive tests, allowing curves to be obtained for both build and transverse directions in various locations, indicate that there is no anisotropy anywhere in these materials. This is consistent with electron backscattered diffraction results, indicating that there is no significant texture in these materials. It is also consistent with the outcomes of PIP testing, which can detect anisotropy with high sensitivity. Furthermore, both PIP testing and compression testing results indicate that the changing growth conditions at different distances from the build plate can lead to strength variations. It seems likely that what has previously been interpreted as anisotropy in the tensile response is in fact due to inhomogeneity of this type.",

keywords = "anisotropy, indentation plastometry, laser packed bed fusion, maraging steels",

author = "Tom Southern and Campbell, {Jimmy E.} and Kourousis, {Kyriakos I.} and Barry Mooney and Tang, {Yuanbo T.} and Clyne, {Trevor William}",

note = "Acknowledgments: Relevant support for TWC has been received from EPSRC (grant EP/I038691/1) and from the Leverhulme Trust, in the form of an International Network grant (IN-2016-004) and an Emeritus Fellowship (EM/2019-038/4). In addition, an ongoing Innovate UK grant (project number 10006185) covers work in this area and JEC is in receipt of a Future Leaders grant from Innovate UK (MR/W01338X/1), which is focused on development of the PIP technique. Financial support has also been received (for KIK and BM) from the Irish Research Council (IRC), through the Government of Ireland Postgraduate Research Programme (grant ID: GOIPG/2017/1041) and from the Faculty of Science and Engineering of the University of Limerick.",

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AU - Southern, Tom

AU - Campbell, Jimmy E.

AU - Kourousis, Kyriakos I.

AU - Mooney, Barry

AU - Tang, Yuanbo T.

AU - Clyne, Trevor William

N1 - Acknowledgments: Relevant support for TWC has been received from EPSRC (grant EP/I038691/1) and from the Leverhulme Trust, in the form of an International Network grant (IN-2016-004) and an Emeritus Fellowship (EM/2019-038/4). In addition, an ongoing Innovate UK grant (project number 10006185) covers work in this area and JEC is in receipt of a Future Leaders grant from Innovate UK (MR/W01338X/1), which is focused on development of the PIP technique. Financial support has also been received (for KIK and BM) from the Irish Research Council (IRC), through the Government of Ireland Postgraduate Research Programme (grant ID: GOIPG/2017/1041) and from the Faculty of Science and Engineering of the University of Limerick.

PY - 2023/7

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N2 - This work concerns the use of profilometry-based indentation plastometry (PIP) to obtain mechanical property information for maraging steel samples produced via an additive manufacturing route (laser powder bed fusion). Bars are produced in both “horizontal” (all material close to the build plate) and “vertical” (progressively increasing distance from the build plate) configurations. Samples are mechanically tested in both as-built and age-hardened conditions. Stress–strain curves from uniaxial testing (tensile and compressive) are compared with those from PIP testing. Tensile test data suggest significant anisotropy, with the horizontal direction harder than the vertical direction. However, systematic compressive tests, allowing curves to be obtained for both build and transverse directions in various locations, indicate that there is no anisotropy anywhere in these materials. This is consistent with electron backscattered diffraction results, indicating that there is no significant texture in these materials. It is also consistent with the outcomes of PIP testing, which can detect anisotropy with high sensitivity. Furthermore, both PIP testing and compression testing results indicate that the changing growth conditions at different distances from the build plate can lead to strength variations. It seems likely that what has previously been interpreted as anisotropy in the tensile response is in fact due to inhomogeneity of this type.

AB - This work concerns the use of profilometry-based indentation plastometry (PIP) to obtain mechanical property information for maraging steel samples produced via an additive manufacturing route (laser powder bed fusion). Bars are produced in both “horizontal” (all material close to the build plate) and “vertical” (progressively increasing distance from the build plate) configurations. Samples are mechanically tested in both as-built and age-hardened conditions. Stress–strain curves from uniaxial testing (tensile and compressive) are compared with those from PIP testing. Tensile test data suggest significant anisotropy, with the horizontal direction harder than the vertical direction. However, systematic compressive tests, allowing curves to be obtained for both build and transverse directions in various locations, indicate that there is no anisotropy anywhere in these materials. This is consistent with electron backscattered diffraction results, indicating that there is no significant texture in these materials. It is also consistent with the outcomes of PIP testing, which can detect anisotropy with high sensitivity. Furthermore, both PIP testing and compression testing results indicate that the changing growth conditions at different distances from the build plate can lead to strength variations. It seems likely that what has previously been interpreted as anisotropy in the tensile response is in fact due to inhomogeneity of this type.

KW - anisotropy

KW - indentation plastometry

KW - laser packed bed fusion

KW - maraging steels

U2 - 10.1002/srin.202200881

DO - 10.1002/srin.202200881

M3 - Article

SN - 1611-3683

VL - 94

JO - Steel Research International

JF - Steel Research International

IS - 7

M1 - 2200881

ER -

Indentation Plastometry for Study of Anisotropy and Inhomogeneity in Maraging Steel Produced by Laser Powder Bed Fusion

Abstract

Bibliographical note

Keywords

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