EFFECT OF MICROSTRUCTURE AND UNIT CELL’S GEOMETRY ON THE COMPRESSIVE MECHANICAL RESPONSE OF ADDITIVELY MANUFACTURED Co-Cr-Mo SHEET I-WP LATTICE

So Yeon Park; Kyu Sik Kim; Bandar Almangour; Kee Ahn Lee

doi:10.24425/amm.2022.141087

EFFECT OF MICROSTRUCTURE AND UNIT CELL’S GEOMETRY ON THE COMPRESSIVE MECHANICAL RESPONSE OF ADDITIVELY MANUFACTURED Co-Cr-Mo SHEET I-WP LATTICE

So Yeon Park, Kyu Sik Kim, Bandar Almangour, Kee Ahn Lee

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Co-Cr-Mo based sheet I-WP lattice was fabricated via laser powder bed fusion. The effect of microstructure and the I-WP shape on compressive mechanical response was investigated. Results of compression test showed that yield strength of the sheet I-WP was 176.3 MPa and that of bulk Co-Cr-Mo (reference material) was 810.4 MPa. By applying Gibson-Ashby analytical model, the yield strength of the lattice was reversely estimated from that of the bulk specimen. The calculated strength of the lattice obtained was 150.7 MPa. The shape of deformed lattice showed collective failure mode, and its microstructure showed that strain-induced martensitic transformation occurred in the overall lattice. The deformation behavior of additively manufactured sheet I-WP lattice was also discussed.

Original language	English
Pages (from-to)	1525-1529
Number of pages	5
Journal	Archives of Metallurgy and Materials
Volume	67
Issue number	4
DOIs	https://doi.org/10.24425/amm.2022.141087
State	Published - 2022

Bibliographical note

Publisher Copyright:
© 2022. The Author(s).

Keywords

Co-Cr-Mo
Compressive mechanical response
Laser powder bed fusion
sheet I-WP lattice
Strain-induced martensitic transformation

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10.24425/amm.2022.141087

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title = "EFFECT OF MICROSTRUCTURE AND UNIT CELL{\textquoteright}S GEOMETRY ON THE COMPRESSIVE MECHANICAL RESPONSE OF ADDITIVELY MANUFACTURED Co-Cr-Mo SHEET I-WP LATTICE",

abstract = "Co-Cr-Mo based sheet I-WP lattice was fabricated via laser powder bed fusion. The effect of microstructure and the I-WP shape on compressive mechanical response was investigated. Results of compression test showed that yield strength of the sheet I-WP was 176.3 MPa and that of bulk Co-Cr-Mo (reference material) was 810.4 MPa. By applying Gibson-Ashby analytical model, the yield strength of the lattice was reversely estimated from that of the bulk specimen. The calculated strength of the lattice obtained was 150.7 MPa. The shape of deformed lattice showed collective failure mode, and its microstructure showed that strain-induced martensitic transformation occurred in the overall lattice. The deformation behavior of additively manufactured sheet I-WP lattice was also discussed.",

keywords = "Co-Cr-Mo, Compressive mechanical response, Laser powder bed fusion, sheet I-WP lattice, Strain-induced martensitic transformation",

author = "Park, {So Yeon} and Kim, {Kyu Sik} and Bandar Almangour and Lee, {Kee Ahn}",

note = "Publisher Copyright: {\textcopyright} 2022. The Author(s).",

year = "2022",

doi = "10.24425/amm.2022.141087",

language = "English",

volume = "67",

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AU - Park, So Yeon

AU - Kim, Kyu Sik

AU - Almangour, Bandar

AU - Lee, Kee Ahn

PY - 2022

Y1 - 2022

N2 - Co-Cr-Mo based sheet I-WP lattice was fabricated via laser powder bed fusion. The effect of microstructure and the I-WP shape on compressive mechanical response was investigated. Results of compression test showed that yield strength of the sheet I-WP was 176.3 MPa and that of bulk Co-Cr-Mo (reference material) was 810.4 MPa. By applying Gibson-Ashby analytical model, the yield strength of the lattice was reversely estimated from that of the bulk specimen. The calculated strength of the lattice obtained was 150.7 MPa. The shape of deformed lattice showed collective failure mode, and its microstructure showed that strain-induced martensitic transformation occurred in the overall lattice. The deformation behavior of additively manufactured sheet I-WP lattice was also discussed.

AB - Co-Cr-Mo based sheet I-WP lattice was fabricated via laser powder bed fusion. The effect of microstructure and the I-WP shape on compressive mechanical response was investigated. Results of compression test showed that yield strength of the sheet I-WP was 176.3 MPa and that of bulk Co-Cr-Mo (reference material) was 810.4 MPa. By applying Gibson-Ashby analytical model, the yield strength of the lattice was reversely estimated from that of the bulk specimen. The calculated strength of the lattice obtained was 150.7 MPa. The shape of deformed lattice showed collective failure mode, and its microstructure showed that strain-induced martensitic transformation occurred in the overall lattice. The deformation behavior of additively manufactured sheet I-WP lattice was also discussed.

KW - Co-Cr-Mo

KW - Compressive mechanical response

KW - Laser powder bed fusion

KW - sheet I-WP lattice

KW - Strain-induced martensitic transformation

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DO - 10.24425/amm.2022.141087

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JO - Archives of Metallurgy and Materials

JF - Archives of Metallurgy and Materials

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EFFECT OF MICROSTRUCTURE AND UNIT CELL’S GEOMETRY ON THE COMPRESSIVE MECHANICAL RESPONSE OF ADDITIVELY MANUFACTURED Co-Cr-Mo SHEET I-WP LATTICE

Abstract

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Keywords

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