A novel control approach for the droplet detachment in rapid prototyping by 3D welding

Gas metal arc welding (GMAW) of steel in argon-rich shielding usually featu res free-metal transfer and short-circuiting metal transfer. Projected spra y transfer in one droplet per pulse (ODPP) mode in combination with the dro plet detachment feedback control is one of the most effective approaches to guarantee high weld quality. This paper explores new methods for controlli ng mass and heat transfer based on droplet detachment behavior in rapid pro totyping by 3D welding. Three groups of experiments are performed based on the different welding current wave forms: pure square wave, square wave com bined with sine wave (combined wave), and pure sine wave. Compared with the pure square wave form, the combined wave form can generate a weld bead wit h a more narrow and shallow penetration profile (the width and depth are 3. 04 mm and 0.22 mm, respectively). When a pure sine wave form is used, the d roplet is forced to oscillate once at the wire tip (the oscillation cycle e quals the pulse cycle) and then detaches smoothly: the droplet is accompani ed by a characteristically harmonious sound. Recorded images show that the droplet in a square or combined wave form can be forced to oscillate twice (the oscillation cycle equals half of the pulsed cycle) before it detaches. Careful selection of parameters in required to generate multiple oscillati ons for the droplet before it detaches. Photos of weld cross section reveal that the penetration profile can be greatly improved using a combined wave form. The results achieved are not only effective for mass and heat contro l in rapid prototyping by 3D welding, but also are beneficial for future in vestigation of the droplet detachment behavior in GMAW.