Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser
In this study, CoCrMo cuboid samples were deposited on a CuZrCr substrate using laser powder bed fusion (L-PBF) technology to investigate the influence of process parameters and laser remelting strategies on the mechanical properties and interface characteristics of multi-metals. This study found th...
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sg-ntu-dr.10356-1806032024-10-19T16:48:58Z Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser Zhang, Hao Jin, Xiang Xiao, Zhongmin Yao, Liming School of Mechanical and Aerospace Engineering Engineering Additive manufacturing Dissimilar alloy In this study, CoCrMo cuboid samples were deposited on a CuZrCr substrate using laser powder bed fusion (L-PBF) technology to investigate the influence of process parameters and laser remelting strategies on the mechanical properties and interface characteristics of multi-metals. This study found that process parameters and laser scanning strategies had a significant influence on the mechanical properties and interface characteristics. Samples fabricated with an EV ≤ 20 J/mm3 showed little tensile ductility. As the volumetric energy density (EV) increased to a range between 40 J/mm3 and 100 J/mm3, the samples achieved the desired mechanical properties, with a strong interface combining the alloys. However, an excessive energy density could result in cracks due to thermal stress. Laser remelting significantly improved the interface properties, especially when the EV was below 40 J/mm3. Variances in the EV showed little influence on the hardness at the CuZrCr end, while the hardness at the interface and the CoCrMo end showed an increasing and decreasing trend with an increase in the EV, respectively. Interface characterization showed that when the EV was greater than 43 J/mm3, the main defects in the L-PBF CoCrMo samples were thermal cracks, which gradually changed to pores with a lack of fusion when the EV decreased. This study provides theoretical and technical support for the manufacturing of multi-metal parts using L-PBF technology. Nanyang Technological University Published version This research was funded by the Singapore Centre for 3D Printing (SC3DP) [001163-00010], the State Key Laboratory of Robotics and Systems (HIT) [SKLRS-2023-KF-24], the International Scientific and Technological Cooperation project [GUIQ0700500523], and the China Scholarship Council [202306230376]. 2024-10-14T08:13:12Z 2024-10-14T08:13:12Z 2024 Journal Article Zhang, H., Jin, X., Xiao, Z. & Yao, L. (2024). Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser. Micromachines, 15(6), 765-. https://dx.doi.org/10.3390/mi15060765 2072-666X https://hdl.handle.net/10356/180603 10.3390/mi15060765 38930735 2-s2.0-85197123063 6 15 765 en 001163-00010 Micromachines © 2024 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https:// creativecommons.org/licenses/by/ 4.0/). application/pdf |
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Engineering Additive manufacturing Dissimilar alloy Zhang, Hao Jin, Xiang Xiao, Zhongmin Yao, Liming Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser |
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In this study, CoCrMo cuboid samples were deposited on a CuZrCr substrate using laser powder bed fusion (L-PBF) technology to investigate the influence of process parameters and laser remelting strategies on the mechanical properties and interface characteristics of multi-metals. This study found that process parameters and laser scanning strategies had a significant influence on the mechanical properties and interface characteristics. Samples fabricated with an EV ≤ 20 J/mm3 showed little tensile ductility. As the volumetric energy density (EV) increased to a range between 40 J/mm3 and 100 J/mm3, the samples achieved the desired mechanical properties, with a strong interface combining the alloys. However, an excessive energy density could result in cracks due to thermal stress. Laser remelting significantly improved the interface properties, especially when the EV was below 40 J/mm3. Variances in the EV showed little influence on the hardness at the CuZrCr end, while the hardness at the interface and the CoCrMo end showed an increasing and decreasing trend with an increase in the EV, respectively. Interface characterization showed that when the EV was greater than 43 J/mm3, the main defects in the L-PBF CoCrMo samples were thermal cracks, which gradually changed to pores with a lack of fusion when the EV decreased. This study provides theoretical and technical support for the manufacturing of multi-metal parts using L-PBF technology. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Zhang, Hao Jin, Xiang Xiao, Zhongmin Yao, Liming |
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Article |
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Zhang, Hao Jin, Xiang Xiao, Zhongmin Yao, Liming |
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Zhang, Hao |
title |
Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser |
title_short |
Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser |
title_full |
Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser |
title_fullStr |
Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser |
title_full_unstemmed |
Mechanical properties and interfacial characterization of additive-manufactured CuZrCr/CoCrMo multi-metals fabricated by powder bed fusion using pulsed wave laser |
title_sort |
mechanical properties and interfacial characterization of additive-manufactured cuzrcr/cocrmo multi-metals fabricated by powder bed fusion using pulsed wave laser |
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2024 |
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https://hdl.handle.net/10356/180603 |
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1814777778330927104 |