Product Code: JLA_18_3_192

Authors:
L. S. Mayboudi
A. M. Birk
G. Zak
Mechanical and Materials Engineering, Queen’s University, Kingston, Ontario K7L 3N6, Canada

P. J. Bates
Chemistry and Chemical Engineering, Royal Military College, Kingston, Ontario K7K 7B4, Canada

Recent years have seen wider application of laser transmission welding (LTW) as a means for joining of plastic components. Advantages of LTW arise from it being a contact-free method for delivering precisely controlled energy to the surfaces of the welded components and from flexibility with regard to welding geometry afforded by the laser being under computer control. LTW involves a laser beam passing through a laser-transparent component being absorbed by the laser-absorbent component at the weld interface. Heat generated at the interface melts a thin layer of plastic in both components and thus forms a joint through molecular interdiffusion. To form a strong bond, it is important that the weld interface is exposed to sufficient heat to melt the polymer without degrading it. Delivery of the thermal energy by the laser beam is affected by process parameters, such as laser power, scan speed, beam spot size, and material properties, such as absorptivity, presence of reinforcements, and other additives. Development of a model for this thermal process capable of accurately predicting the extent of the molten zone in space and over time is vital for in-depth understanding of LTW and its optimization. This article presents a two-dimensional (2D) thermal model of LTW solved with the finite element method. A modified T-like joint geometry is modeled for unreinforced nylon 6 specimens. This thermal model addresses heating and cooling stages in a laser welding process. The 2D model is capable of predicting the molten zone depth as well as transient temperature distribution along the weld line. The molten zone predicted by the model was compared to the one observed from the cross sections of unfilled Nylon 6 modified T-joint specimens welded using a 150 W diode laser.