Phenomenological modelling of direct laser metal deposition for single tracks

The direct laser metal deposition (DLMD) is an emerging technology in the additive manufacturing field, which is becoming widely adopted in several industrial applications. The optimal selection of process parameters is critical, given the cost of physical tests and the requirement for high-quality...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2020-12, Vol.111 (7-8), p.1955-1970
Main Authors: Mazzarisi, Marco, Campanelli, Sabina Luisa, Angelastro, Andrea, Dassisti, Michele
Format: Article
Language:English
Subjects:
Alloy powders
CAE) and Design
Computer-Aided Engineering (CAD
Engineering
Exponents
Feed rate
Forecasting
Industrial and Production Engineering
Industrial applications
Laser deposition
Lasers
Mathematical models
Mechanical Engineering
Media Management
New technology
Nickel base alloys
Original Article
Physical properties
Physical tests
Process parameters
Superalloys
Thermal diffusivity
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Summary:The direct laser metal deposition (DLMD) is an emerging technology in the additive manufacturing field, which is becoming widely adopted in several industrial applications. The optimal selection of process parameters is critical, given the cost of physical tests and the requirement for high-quality manufacturing. Correct forecasting of process parameters using predictive physical models is a viable alternative to shorten the setup phase and improve the sustainability. In this paper, firstly, several models available so far in the literature are reviewed, and then, a general model is derived to evaluate the best combination of process parameters in single track operations. The proposed phenomenological model allows simple forecasting based on three main process parameters: laser power (P), powder feed rate (F) and translation speed (V). An innovative approach is proposed to generalise the model and overcome the “try and error” method used in numerous works to determine the exponents ( α , β , γ ). The model was designed considering the physical parameters which best explained the variability of the exponents: the thermal diffusivity of the base material and the density of the powder material. The best ranges of the process parameter exponents are suggested to establish the most suitable combined parameters for the prediction of geometric characteristics of the clad. The potentialities of the model are proven based on an experimental case performed over a commercially available Nickel-based super-alloy powder. New formulations are recommended, which are in good agreement with the behaviours defined in the literature, as shown in the test case.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-020-06204-x