Details

Autor(en) / Beteiligte

• Angelastro, A.
• Campanelli, S.L.
• Casalino, G.

Titel

Statistical analysis and optimization of direct metal laser deposition of 227-F Colmonoy nickel alloy

Ist Teil von

• Optics and laser technology, 2017-09, Vol.94, p.138-145

Ort / Verlag

Kidlington: Elsevier Ltd

Erscheinungsjahr

2017

Link zum Volltext

Quelle

Elsevier ScienceDirect Journals Complete

Beschreibungen/Notizen

• •Colmonoy 30 layers samples were built and characterized.•Roughness, adhesion, microstructure, microhardness and density were studied.•The hatch spacing and step height optimal values were determined.•Good adhesion to the substrate and low defects microstructure were obtained.•High density and low roughness samples were obtained. This paper presents a study on process parameters and building strategy for the deposition of Colmonoy 227-F powder by CO2 laser with a focal spot diameter of 0.3mm. Colmonoy 227-F is a nickel alloy especially designed for mold manufacturing. The substrate material is a 10mm thick plate of AISI 304 steel. A commercial CO2 laser welding machine was equipped with a low-cost powder feeding system. In this work, following another one in which laser power, scanning speed and powder flow rate had been studied, the effects of two important process parameters, i.e. hatch spacing and step height, on the properties of the built parts were analysed. The explored ranges of hatch spacing and step height were respectively 150–300μm and 100–200μm, whose dimensions were comparable with that of the laser spot. The roughness, adhesion, microstructure, microhardness and density of the manufactured specimens were studied for multi-layer samples, which were made of 30 layers. The statistical significance of the studied process parameters was assessed by the analysis of the variance. The process parameters used allowed to obtain both first layer-to-substrate and layer-to-layer good adhesions. The microstructure was fine and almost defect-free. The microhardness of the deposited material was about 100HV higher than that of the starting powder. The density as high as 98% of that of the same bulk alloy was more than satisfactory. Finally, simultaneous optimization of density and roughness was performed using the contour plots.