Litcius/Paper detail

Towards hybrid laser-arc based directed energy deposition: Understanding bead formation through mathematical modeling for additive manufacturing

Angshuman Kapil, Tetsuo Suga, Manabu Tanaka, Abhay Sharma

2022Journal of Manufacturing Processes28 citationsDOIOpen Access PDF

Abstract

This study highlights three phenomena in directed energy deposition using hybrid laser-arc: bead formation, change in the bead shape because of laser-arc interaction, and formation of defects. Unlike the arc-based deposition, the shape of the hybrid laser-arc bead differs from the pre-conceived parabolic or cosine form, which necessitates a new bead model. The laser-induced flow and preheating of wire electrode widen the molten pool width and cause a depression of the top surface of the deposited bead. Consequently, the fixed critical offset distance for multi-pass deposition (e.g., 0.66 or 0.73 times of the bead width, based on the flat or tangent overlapping model for arc-based deposition) does not yield the optimal flat surface for the hybrid laser-arc deposition. In this work, first, a parametric study assesses bead formation and defect phenomenon for high-strength steel as a candidate material, followed by an evaluation of the existing bead models for the appropriateness of the shape of defect-free hybrid laser-arc beads. Results indicate that a parabola composited with a unimodal beta distribution - that accounts for the laser influence (power and laser-arc distance) on the bead shape - is more responsive to the bead shape variation and is substantially more accurate than the existing models. Increasing laser power and laser-arc distance significantly changes the bead shape and reduces the critical offset distance. The traverse speed is the most critical factor followed by welding current leading to defect-free bead deposition. It is envisioned that the fundamental understanding developed as a result of the present investigation will provide a direction for hybrid laser-arc based additive manufacturing of several material classes, many of which are not weldable and therefore not additively manufactured by arc-based deposition.

Topics & Concepts

Materials scienceBeadLaserLaser power scalingDeposition (geology)Arc (geometry)Composite materialOpticsMechanical engineeringPaleontologyEngineeringSedimentPhysicsBiologyAdditive Manufacturing Materials and ProcessesWelding Techniques and Residual StressesLaser Material Processing Techniques