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Derivation of material properties using small punch and shear punch test methods

Robert Lancaster Orcid Logo, Spencer Jeffs Orcid Logo, Ben Haigh, Nick Barnard

Materials & Design, Volume: 215, Start page: 110473

Swansea University Authors: Robert Lancaster Orcid Logo, Spencer Jeffs Orcid Logo, Ben Haigh, Nick Barnard

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Abstract

The Small Punch (SP) and Shear Punch (ShP) tests are well established mechanical test approaches that have found application in several industrial sectors for material ranking and mechanical property estimation, particularly where more conventional approaches are inhibited. Despite the advantages th...

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Published in: Materials & Design
ISSN: 0264-1275
Published: Elsevier BV 2022
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URI: https://cronfa.swan.ac.uk/Record/cronfa59463
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spelling 2022-10-31T17:03:32.3576109 v2 59463 2022-02-28 Derivation of material properties using small punch and shear punch test methods e1a1b126acd3e4ff734691ec34967f29 0000-0002-1365-6944 Robert Lancaster Robert Lancaster true false 6ff76d567df079d8bf299990849c3d8f 0000-0002-2819-9651 Spencer Jeffs Spencer Jeffs true false 041f978ff61d78231663415fa21c9cdf Ben Haigh Ben Haigh true false dc4a58e614bc6a1d99812a3acfdd9034 Nick Barnard Nick Barnard true false 2022-02-28 MTLS The Small Punch (SP) and Shear Punch (ShP) tests are well established mechanical test approaches that have found application in several industrial sectors for material ranking and mechanical property estimation, particularly where more conventional approaches are inhibited. Despite the advantages that the two test methodologies have to offer, the main drawback is the complex understanding of the mechanical data generated from the experiments and how it can be correlated to more recognised properties. Typically, the most desired properties relate to the uniaxial properties of yield stress, ultimate tensile strength and ductility, but to date, there is no single robust and overarching approach for correlating such properties for a wide array of metallic materials that exhibit varying levels of ductility. This paper will for the first time directly compare properties obtained from a series of uniaxial tensile, SP and ShP tests across several metallic materials, and look to establish and correlate equivalent properties across the different test types. The materials investigated range from commercially pure entities to more advanced alloy systems. The generated results, empirical relationships and numerical simulations will inform which materials can be correlated across the different test regimes, and identify why the relationship in certain materials breaks down. Journal Article Materials & Design 215 110473 Elsevier BV 0264-1275 1 3 2022 2022-03-01 10.1016/j.matdes.2022.110473 COLLEGE NANME Materials Science and Engineering COLLEGE CODE MTLS Swansea University 2022-10-31T17:03:32.3576109 2022-02-28T08:55:20.4026356 Faculty of Science and Engineering School of Engineering and Applied Sciences - Materials Science and Engineering Robert Lancaster 0000-0002-1365-6944 1 Spencer Jeffs 0000-0002-2819-9651 2 Ben Haigh 3 Nick Barnard 4 59463__22541__077ca579141d45148ada2d5808c00568.pdf 59463.pdf 2022-03-07T17:04:01.7679381 Output 4260465 application/pdf Version of Record true Copyright: 2022 The Authors. This is an open access article under the CC BY license true eng http://creativecommons.org/licenses/by/4.0/
title Derivation of material properties using small punch and shear punch test methods
spellingShingle Derivation of material properties using small punch and shear punch test methods
Robert Lancaster
Spencer Jeffs
Ben Haigh
Nick Barnard
title_short Derivation of material properties using small punch and shear punch test methods
title_full Derivation of material properties using small punch and shear punch test methods
title_fullStr Derivation of material properties using small punch and shear punch test methods
title_full_unstemmed Derivation of material properties using small punch and shear punch test methods
title_sort Derivation of material properties using small punch and shear punch test methods
author_id_str_mv e1a1b126acd3e4ff734691ec34967f29
6ff76d567df079d8bf299990849c3d8f
041f978ff61d78231663415fa21c9cdf
dc4a58e614bc6a1d99812a3acfdd9034
author_id_fullname_str_mv e1a1b126acd3e4ff734691ec34967f29_***_Robert Lancaster
6ff76d567df079d8bf299990849c3d8f_***_Spencer Jeffs
041f978ff61d78231663415fa21c9cdf_***_Ben Haigh
dc4a58e614bc6a1d99812a3acfdd9034_***_Nick Barnard
author Robert Lancaster
Spencer Jeffs
Ben Haigh
Nick Barnard
author2 Robert Lancaster
Spencer Jeffs
Ben Haigh
Nick Barnard
format Journal article
container_title Materials & Design
container_volume 215
container_start_page 110473
publishDate 2022
institution Swansea University
issn 0264-1275
doi_str_mv 10.1016/j.matdes.2022.110473
publisher Elsevier BV
college_str Faculty of Science and Engineering
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hierarchy_top_id facultyofscienceandengineering
hierarchy_top_title Faculty of Science and Engineering
hierarchy_parent_id facultyofscienceandengineering
hierarchy_parent_title Faculty of Science and Engineering
department_str School of Engineering and Applied Sciences - Materials Science and Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Materials Science and Engineering
document_store_str 1
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description The Small Punch (SP) and Shear Punch (ShP) tests are well established mechanical test approaches that have found application in several industrial sectors for material ranking and mechanical property estimation, particularly where more conventional approaches are inhibited. Despite the advantages that the two test methodologies have to offer, the main drawback is the complex understanding of the mechanical data generated from the experiments and how it can be correlated to more recognised properties. Typically, the most desired properties relate to the uniaxial properties of yield stress, ultimate tensile strength and ductility, but to date, there is no single robust and overarching approach for correlating such properties for a wide array of metallic materials that exhibit varying levels of ductility. This paper will for the first time directly compare properties obtained from a series of uniaxial tensile, SP and ShP tests across several metallic materials, and look to establish and correlate equivalent properties across the different test types. The materials investigated range from commercially pure entities to more advanced alloy systems. The generated results, empirical relationships and numerical simulations will inform which materials can be correlated across the different test regimes, and identify why the relationship in certain materials breaks down.
published_date 2022-03-01T04:11:39Z
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