Multi-Robot Scan-n-Print for Wire Arc Additive Manufacturing

TL;DR

This paper introduces a multi-robot system for wire arc additive manufacturing that actively monitors and adjusts the printing process in real-time, significantly improving geometric accuracy for complex metal parts.

Contribution

It presents a novel multi-robot framework integrating sensing and control for WAAM, enabling real-time adjustments based on height profile measurements.

Findings

Improved geometric accuracy over open-loop methods.

Effective coordination of multiple robots during printing.

Successful application on complex turbine blade shape.

Abstract

Robotic Wire Arc Additive Manufacturing (WAAM) is a metal additive manufacturing technology, offering flexible 3D printing while ensuring high quality near-net-shape final parts. However, WAAM also suffers from geometric imprecision, especially for low-melting-point metal such as aluminum alloys. In this paper, we present a multi-robot framework for WAAM process monitoring and control. We consider a three-robot setup: a 6-dof welding robot, a 2-dof trunnion platform, and a 6-dof sensing robot with a wrist-mounted laser line scanner measuring the printed part height profile. The welding parameters, including the wire feed rate, are held constant based on the materials used, so the control input is the robot path speed. The measured output is the part height profile. The planning phase decomposes the target shape into slices of uniform height. During runtime, the sensing robot scans each printed layer, and the robot path speed for the next layer is adjusted based on the deviation from the desired profile. The adjustment is based on an identified model correlating the path speed to change in height. The control architecture coordinates the synchronous motion and data acquisition between all robots and sensors. Using a three-robot WAAM testbed, we demonstrate significant improvements of the closed loop scan-n-print approach over the current open loop result on both a flat wall and a more complex turbine blade shape.