Leonardo Caprio scite author profile

The definition of process parameters depending on the geometry of the workpiece is one of the main challenges for Selective Laser Melting (SLM). The possibility to use different emission modes is an essential feature of the contemporary fiber lasers, which still requires further attention for controlling the melt pool size. Most of the commercially available SLM systems operates with continuous wave (CW) emission lasers. As a consequence, a substantial effort has been directed towards obtaining full densification by considering the variation of process parameters in CW modality. Pulsed wave (PW) emission achieved by power modulation of a fiber laser is preferred by a smaller fraction of the industrial SLM systems. The differences between the two emission regimes, advantages and disadvantages in their use have not been fully understood.Accordingly, this work proposes a comparative study between the two emission regimes in SLM, namely PW and CW. For this purpose, a single mode fiber laser is coupled to a prototype SLM system composed of an automated powder-bed and a scanner head. The laser source is extensively characterized for pulsed wave emission characteristics in a power modulated regime. Conditions providing the same energy content over the single track were determined and their effect on single track densification is studied. High speed imaging (HSI) is used to observe the differences in the melt pool formation in situ. The overall results confirm that CW emission provides a larger and more stable molten pool during the process, resulting in higher deposition rates. On the other hand, under stable conditions, PW emission provides relatively narrow tracks, which might be problematic for porosity formation and at the same time useful for the production of fine geometries.

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Limits and solutions in processing pure Cu via selective laser melting using a high-power single-mode fiber laser

Colopi

Demir

Caprio

et al. 2019

Int J Adv Manuf Technol

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The demand for additive manufacturing (AM) of Cu and its alloys shows an increased trend from the energy and heat transfer related applications. Selective laser melting (SLM) is amongst the key AM processes for metals, providing high geometrical accuracy and design flexibility. The technology is most commonly employed using high brilliance fiber lasers operating at 1 m. However, the elevated reflectivity of Cu at this wavelength, combined with its high thermal conductivity is the cause for a highly unstable process, whereby pore-free products are difficult to obtain. Accordingly, the present work explores the limitations in processing pure Cu powders with a 1 kW single mode fiber laser providing solutions and different strategies for improving part quality. In particular, the power level requirements, as well as build plate material, is assessed through an analytical model. Later on, the process parameters were studied for single and multi-pass melting strategies.The results demonstrate that a correct sequence of multi-pass strategy can improve the part density up to 99.10.2% with an industrially acceptable build rate of 12.6 cm3/h.

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Complementary use of pulsed and continuous wave emission modes to stabilize melt pool geometry in laser powder bed fusion

Demir

Mazzoleni

Caprio

et al. 2019

Optics & Laser Technology

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Defect-free laser powder bed fusion of Ti–48Al–2Cr–2Nb with a high temperature inductive preheating system

et al. 2020

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In the industrial panorama, laser powder bed fusion (LPBF) systems enable the near net shaping of metal powders into complex geometries with unique design features. This makes the technology appealing for many industrial applications, which require high performance materials combined with lightweight design, lattice structures and organic forms. However, many of the alloys that would be ideal for the realisation of these functional components are classified as difficult to weld due to their cracking sensitivity. γ-TiAl alloys are currently processed via electron beam melting (EBM) to produce components for energy generation applications. The EBM process provides crack-free processing thanks to the preheating stages between layers, but lacks geometrical precision. The use of LPBF could provide the means for higher precision, and therefore an easier post-processing stage. However, industrial LPBF systems employ resistive heating elements underneath the base plate which do not commonly reach the high temperatures required for the processing of γ-TiAl alloys. Thus, elevated temperature preheating of the build part and control over the cooling rate after the deposition process is concluded are amongst the features which require further investigations. In this work, the design and implementation of a novel inductive high temperature LPBF system to process Ti-48Al-2Cr-2Nb is presented. Specimens were built with preheating at 800°C and the cooling rate at the end of the build was controlled at 5°C min −1 . Crack formation was suppressed and apparent density in excess of 99% was achieved.

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Leonardo Caprio

Selective laser melting of pure Cu with a 1 kW single mode fiber laser

Comparative study between CW and PW emissions in selective laser melting

Limits and solutions in processing pure Cu via selective laser melting using a high-power single-mode fiber laser

Complementary use of pulsed and continuous wave emission modes to stabilize melt pool geometry in laser powder bed fusion

Defect-free laser powder bed fusion of Ti–48Al–2Cr–2Nb with a high temperature inductive preheating system

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