Electron Beam-Melting and Laser Powder Bed Fusion of Ti6Al4V: Transferability of Process Parameters

Megahed, Sandra; Aniko, Vadim; Schleifenbaum, Johannes Henrich

doi:10.3390/met12081332

Cited by 17 publications

(2 citation statements)

References 42 publications

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“…In another technique of PBD that uses tungsten electron beam instead of laser light to fuse metal powder particles in layer-by-layer fashion under vacuum condition is called Electron Beam Melting (EBM). However, the process requires a base material that is conductive in nature [69]. In a study, the authors have taken the advantage of EBM combined with computational biology to interconnect the foamed structure inside the scaffold.…”

Section: Powder Bed Fusionmentioning

confidence: 99%

Designing of gradient scaffolds and their applications in tissue regeneration

et al. 2023

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Section: Powder Bed Fusionmentioning

confidence: 99%

Designing of gradient scaffolds and their applications in tissue regeneration

et al. 2023

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“…Diferentes autores han descrito que la modificación de los parámetros de manufactura afecta la calidad geométrica y superficial de la pieza que se está manufacturando, al igual que algunas propiedades mecánicas de la pieza [13], [23], [24], [25].…”

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Efects of scan speed and laser power at the geometic quality of materials manufactured using Selective Laser Fusion SLF

Correa¹,

Rodríguez²

2023

Proceedings of the 21th LACCEI International Multi-Conference for Engineering, Education and Technology (LACCEI 2023): “Leaders

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Effect of powder particle size distribution and contouring on build quality in electron beam powder bed fusion of a medium-C hot-work tool steel

Sullivan,

Sharif Hedås,

Jerhamre Engström

et al. 2023

Int J Adv Manuf Technol

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An electron beam powder bed fusion (EPBF) printability study of a medium-C hot-work tool steel with focus on part density and surface roughness was performed using three different powder particle size distributions (PSDs) of 45–105 $$\mathrm{\mu mmm}$$ μ mmm (typical for EPBF), 20–60 $$\mathrm{\mu mmm}$$ μ mmm (typical for laser beam powder bed fusion), and a 50–50 wt.% mixture of these two powders. First, acceptable process parameter windows were generated based on as-printed density for each PSD. Full density parts (at least 99.5% dense according to NIST) were produced using the 20–60 $$\mathrm{\mu mmm}$$ μ mmm PSD and the mix PSD. Fifteen different contouring strategies were also tested for potential improvement of the as-printed side surface roughnesses, which ranged from 23.3 to 25.7 $$\mathrm{\mu mmm}$$ μ mmm among the three PSDs. Side surface roughness as low as 13.8 $$\mathrm{\mu mmm}$$ μ mmm was attained by using contouring strategies employing two contouring lines, which were typically observed to be more effective than one-line strategies. Overall, the 20–60 $$\mathrm{\mu mmm}$$ μ mmm PSD was determined to convey a better as-printed build quality over a wider range of parameters without sacrificing process productivity.

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Electron Beam-Melting and Laser Powder Bed Fusion of Ti6Al4V: Transferability of Process Parameters

Cited by 17 publications

References 42 publications

Designing of gradient scaffolds and their applications in tissue regeneration

Designing of gradient scaffolds and their applications in tissue regeneration

Efects of scan speed and laser power at the geometic quality of materials manufactured using Selective Laser Fusion SLF

Effect of powder particle size distribution and contouring on build quality in electron beam powder bed fusion of a medium-C hot-work tool steel

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