Accurate Inverse Process Optimization Framework in Laser Directed Energy Deposition

TL;DR

This paper introduces AIDED, a machine learning and genetic algorithm-based framework that accurately predicts and optimizes laser directed energy deposition process parameters, significantly reducing time and enhancing versatility for manufacturing complex 3D metal components.

Contribution

The study develops a novel inverse process optimization framework combining machine learning and genetic algorithms for laser DED, enabling rapid, accurate, and transferable process parameter determination.

Findings

High accuracy in predicting melt pool geometries (R2 > 0.97)

Successful inverse identification of process parameters within 1-3 hours

Validated framework effectiveness through experimental targets and material transferability

Abstract

In additive manufacturing (AM), particularly for laser-based metal AM, process optimization is crucial to the quality of products and the efficiency of production. The identification of optimal process parameters out of a vast parameter space, however, is a daunting task. Despite advances in simulations, the process optimization for specific materials and geometries is developed through a time-consuming trial-and-error approach, which often lacks the versatility to address multiple optimization objectives. Machine learning (ML) provides a powerful tool to accelerate the optimization process, but most current studies focus on simple single-track prints, which hardly translate to manufacturing 3D components for engineering applications. In this study, we develop an Accurate Inverse process optimization framework in laser Directed Energy Deposition (AIDED), based on machine learning models and a genetic algorithm, to aid process optimization in laser DED processes. Using the AIDED, we demonstrate the following: (i) Accurately predict single-track (R2 score 0.995), multi-track (R2 score 0.969), and multi-layer (1.07% and 10.75% error in width and height, respectively) cross-sectional melt pool geometries directly from process parameters; (ii) Determine appropriate hatch spacing and layer thickness for fabricating fully dense (density > 99.9%) multi-track and multi-layer prints; (iii) Inversely identify optimal process parameters directly from customizable application objectives within 1-3 hours. We also validate the effectiveness of the AIDED experimentally by achieving two exemplary targets: fast print speed and fine print resolution. Furthermore, we show the high transferability of the framework from stainless steel to pure nickel. With AIDED, we pave a new way for ''aiding'' the process optimization in the laser-based AM processes that is applicable to a wide range of materials.