Fundamental understanding of the interaction of continuous wave laser with aluminium

Fundamental understanding of the interaction of continuous wave laser with aluminium

In welding, the depth of penetration, weld profile and the corresponding thermal cycle are the three basic outcomes that a user wishes to control flexibly. In laser welding applications, controlled application of power and energy density is the key to achieve predictable control of these characteris...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology Vol. 93; no. 9-12; pp. 3165 - 3174
Main Authors: Coroado, Júlio, Meco, Sónia, Williams, Stewart, Ganguly, Supriyo, Suder, Wojciech, Quintino, Luísa, Assunção, Eurico
Format: Journal Article
Language:English
Published: London Springer London 01-12-2017
Springer Nature B.V
Subjects:
Aluminum base alloys
CAE) and Design
Computer-Aided Engineering (CAD
Continuous wave lasers
Engineering
Flux density
Industrial and Production Engineering
Interaction parameters
Laser beam welding
Lasers
Low carbon steels
Mathematical models
Mechanical Engineering
Media Management
Original Article
Penetration
Power factor
Temperature profiles
Thermodynamic properties
Weld metal
Welding parameters
Weld width
Power factor model
Interaction time
Laser beam diameter
Depth of penetration
Laser welding
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Summary:In welding, the depth of penetration, weld profile and the corresponding thermal cycle are the three basic outcomes that a user wishes to control flexibly. In laser welding applications, controlled application of power and energy density is the key to achieve predictable control of these characteristics. Creation of an analytical model is an important step towards understanding the underpinning science of laser metal interaction in controlling the depth, bead geometry and thereby temperature profile of a weld. The “power factor model”, which correlates the power applied per unit length to the laser metal interaction time, has been originally developed and validated for mild steel, guides a user on the selection laser system parameters, to achieve specific weld profile. This study is performed to extend the power factor–interaction time model to aluminium alloys by understanding the underpinning laser aluminium interaction parameters in terms of power density, interaction time, specific point energy and their correlation with the weld bead profiles. Although the power factor and interaction time showed a rectangular hyperbolic relationship, as observed in low carbon steel, for a specific weld depth and profile, the absolute magnitude and the characteristic profile of the curve is different due to the intrinsic differences in physical and thermal properties of aluminium as compared to steel. It was shown that identical depth of penetration but different weld metal profile can be obtained for a specific beam diameter for a range of power and travel speed by keeping the energy input per unit length constant.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-017-0702-6