Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions

Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions

Hybrid ex-situ/in-situ reinforced titanium matrix composites (TMCs) were fabricated by selective laser melting (SLM). The optimized pre-processed 5 wt% B4C/Ti-6Al-4V composite powder feedstock and the un-reinforced Ti-6Al-4V powder were consolidated using energy densities in the range of 50–75 J/mm3...

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Main Authors: Eskandar Fereiduni, Ali Ghasemi, Mohamed Elbestawi
Format: Article
Language:English
Published: Elsevier 2019-12-01
Series:Materials & Design
Online Access:http://www.sciencedirect.com/science/article/pii/S0264127519306239
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spelling doaj-a756321ad626449999b26990de64e46c2020-11-25T01:41:11ZengElsevierMaterials & Design0264-12752019-12-01184Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutionsEskandar Fereiduni0Ali Ghasemi1Mohamed Elbestawi2Corresponding authors.; Department of Mechanical Engineering, McMaster University, Hamilton, ON L8S 4L7, CanadaDepartment of Mechanical Engineering, McMaster University, Hamilton, ON L8S 4L7, CanadaCorresponding authors.; Department of Mechanical Engineering, McMaster University, Hamilton, ON L8S 4L7, CanadaHybrid ex-situ/in-situ reinforced titanium matrix composites (TMCs) were fabricated by selective laser melting (SLM). The optimized pre-processed 5 wt% B4C/Ti-6Al-4V composite powder feedstock and the un-reinforced Ti-6Al-4V powder were consolidated using energy densities in the range of 50–75 J/mm3. Despite the full melting of the powder particles in the monolithic Ti-6Al-4V system, complete melting of the host Ti-6Al-4V constituent in the composite case took place by energy densities exceeding 62.5 J/mm3. Presence of the guest B4C particles surrounding the un-melted/partially melted host particles gave evidence of the non-efficient guest-to-host heat transfer. In-situ formation of (TiB + TiC) reinforcements was discussed based on a mechanism proposing dissolution rather than melting of the guest particles. The degree of dissolution was a significant function of the energy density and the guest particle size. Microstructural evolutions during SLM of 5 wt% B4C/Ti64 composite were studied, and the non-equilibrium solidification sequence was suggested based on the microstructural observations and the equilibrium solidification path. High cooling rates during SLM inhibited some of the liquid and solid-state transformations in the TMCs. This was confirmed by microstructural observations of the arc-melted parts fabricated by the same composite feedstock. The SLM processed TMCs showed 30–80% enhancement in microhardness compared to the unreinforced Ti64. Keywords: Selective laser melting (SLM), Metal matrix composite (MMC), Ti-6Al-4V, In-situ and ex-situ reinforcement, Solidification pathhttp://www.sciencedirect.com/science/article/pii/S0264127519306239
collection DOAJ
language English
format Article
sources DOAJ
author Eskandar Fereiduni
Ali Ghasemi
Mohamed Elbestawi
spellingShingle Eskandar Fereiduni
Ali Ghasemi
Mohamed Elbestawi
Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
Materials & Design
author_facet Eskandar Fereiduni
Ali Ghasemi
Mohamed Elbestawi
author_sort Eskandar Fereiduni
title Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
title_short Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
title_full Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
title_fullStr Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
title_full_unstemmed Selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: Laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
title_sort selective laser melting of hybrid ex-situ/in-situ reinforced titanium matrix composites: laser/powder interaction, reinforcement formation mechanism, and non-equilibrium microstructural evolutions
publisher Elsevier
series Materials & Design
issn 0264-1275
publishDate 2019-12-01
description Hybrid ex-situ/in-situ reinforced titanium matrix composites (TMCs) were fabricated by selective laser melting (SLM). The optimized pre-processed 5 wt% B4C/Ti-6Al-4V composite powder feedstock and the un-reinforced Ti-6Al-4V powder were consolidated using energy densities in the range of 50–75 J/mm3. Despite the full melting of the powder particles in the monolithic Ti-6Al-4V system, complete melting of the host Ti-6Al-4V constituent in the composite case took place by energy densities exceeding 62.5 J/mm3. Presence of the guest B4C particles surrounding the un-melted/partially melted host particles gave evidence of the non-efficient guest-to-host heat transfer. In-situ formation of (TiB + TiC) reinforcements was discussed based on a mechanism proposing dissolution rather than melting of the guest particles. The degree of dissolution was a significant function of the energy density and the guest particle size. Microstructural evolutions during SLM of 5 wt% B4C/Ti64 composite were studied, and the non-equilibrium solidification sequence was suggested based on the microstructural observations and the equilibrium solidification path. High cooling rates during SLM inhibited some of the liquid and solid-state transformations in the TMCs. This was confirmed by microstructural observations of the arc-melted parts fabricated by the same composite feedstock. The SLM processed TMCs showed 30–80% enhancement in microhardness compared to the unreinforced Ti64. Keywords: Selective laser melting (SLM), Metal matrix composite (MMC), Ti-6Al-4V, In-situ and ex-situ reinforcement, Solidification path
url http://www.sciencedirect.com/science/article/pii/S0264127519306239
work_keys_str_mv AT eskandarfereiduni selectivelasermeltingofhybridexsituinsitureinforcedtitaniummatrixcompositeslaserpowderinteractionreinforcementformationmechanismandnonequilibriummicrostructuralevolutions
AT alighasemi selectivelasermeltingofhybridexsituinsitureinforcedtitaniummatrixcompositeslaserpowderinteractionreinforcementformationmechanismandnonequilibriummicrostructuralevolutions
AT mohamedelbestawi selectivelasermeltingofhybridexsituinsitureinforcedtitaniummatrixcompositeslaserpowderinteractionreinforcementformationmechanismandnonequilibriummicrostructuralevolutions
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