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Additive manufacturing of titanium–diamond parts: insights into the laser metal deposition process, powder rheology, mechanical properties and osteoblast cell viability

Nour Mani (School of Engineering, Royal Melbourne Institute of Technology, Melbourne, Australia)
Nhiem Tran (School of Science, Royal Melbourne Insitute of Technology, Melbourne, Australia)
Alan Jones (School of Engineering, Royal Melbourne Institute of Technology, Melbourne, Australia)
Azadeh Mirabedini (School of Engineering, Royal Melbourne Institute of Technology, Melbourne, Australia)
Shadi Houshyar (School of Engineering, Royal Melbourne Institute of Technology, Melbourne, Australia)
Kate Fox (School of Engineering, Royal Melbourne Institute of Technology, Melbourne, Australia)

Rapid Prototyping Journal

ISSN: 1355-2546

Article publication date: 6 September 2024

Issue publication date: 18 November 2024

89

Abstract

Purpose

The purpose of this study is therefore to detail an additive manufacturing process for printing TiD parts for implant applications. Titanium–diamond (TiD) is a new composite that provides biocompatible three-dimensional multimaterial structures. Thus, the authors report a powder-deposition and print optimization strategy to overcome the dual-functionality gap by printing bulk TiD parts. However, despite favorable customization outcomes, relatively few additive manufacturing (AM) feedstock powders offer the biocompatibility required for medical implant and device technologies.

Design/methodology/approach

AM offers a platform to fabricate customized patient-specific parts. Developing feedstock that can be 3D printed into specific 3D structures while providing a favorable interface with the human tissue remains a challenge. Using laser metal deposition, feedstock powder comprising diamond and titanium was co-printed into TiD parts for mechanical testing to determine optimal manufacturing parameters.

Findings

TiD parts were fabricated comprising 30% and 50% diamond. The composite powder had a Hausner ratio of 1.13 and 1.21 for 30% and 50% TiD, respectively. The flow analysis (Carney flow) for TiD 30% and 50% was 7.53 and 5.15 g/s. The authors report that the printing-specific conditions significantly affect the integrity of the printed part and thus provide the optimal manufacturing parameters for structural integrity as determined by micro-computed tomography, nanoindentation and biocompatibility of TiD parts. The hardness, ultimate tensile strength and yield strength for TiD are 4–6 GPa (depending on build position), 426 MPa and 375 MPa, respectively. Furthermore, the authors show that increasing diamond composition to 30% results in higher osteoblast viability and lower bacteria count than titanium.

Originality/value

In this study, the authors provide a clear strategy to manufacture TiD parts with high integrity, performance and biocompatibility, expanding the material feedstock library and paving the way to customized diamond implants. Diamond is showing strong potential as a biomedical material; however, upscale is limited by conventional techniques. By optimizing AM as the avenue to make complex shapes, the authors open up the possibility of patient-specific diamond implant solutions.

Graphical abstarct

Keywords

Citation

Mani, N., Tran, N., Jones, A., Mirabedini, A., Houshyar, S. and Fox, K. (2024), "Additive manufacturing of titanium–diamond parts: insights into the laser metal deposition process, powder rheology, mechanical properties and osteoblast cell viability", Rapid Prototyping Journal, Vol. 30 No. 10, pp. 1989-2006. https://doi.org/10.1108/RPJ-10-2023-0357

Publisher

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Emerald Publishing Limited

Copyright © 2024, Emerald Publishing Limited

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