Manufacturing Technology. X:X | DOI: 10.21062/mft.2026.016

Hybrid ANN–GA Modeling and Experimental Optimization of GMAW-Based Additive Manufacturing of Aluminum 5083 for Enhanced Mechanical Properties

Teephet Chaiyason ORCID...1, Suriya Prasomthong ORCID...1, Panuwat Thosa ORCID...1, Sittichai Charonerat ORCID...1, Phattharapong Keidlaphi ORCID...2
Department of Industrial Technology, Nakhon Phanom University, Nakhon Phanom, Thailand§1
Department of Manufacturing Engineering, Faculty of Engineering and Architecture, Rajamangala University of Technology Suvarnabhumi, Thailand§2

Wire + Arc Additive Manufacturing (WAAM) based on Gas Metal Arc Welding (GMAW) has emerged as a cost-effective and high-deposition process for fabricating large-scale aluminum components. However, its application to non-heat-treatable aluminum 5083 remains limited by thermal-cycle in-stabilities, porosity, and non-uniform mechanical performance. This study presents an integrated experimental and artificial-intelligence framework for optimizing key GMAW parameters—welding current, wire-feed speed, and welding speed—to enhance the mechanical properties of WAAM-fabricated aluminum 5083 walls. An L9 Taguchi design was employed to quantify parameter effects, followed by analysis of variance (ANOVA) to identify dominant factors. Results indicated that weld-ing speed exerted the greatest influence on tensile strength (≈ 58.8 % contribution), whereas wire-feed speed and current primarily affected hardness through solidification behavior. An Artificial Neural Network (ANN) model was then developed to predict tensile strength and hardness with high accuracy (R > 0.99; MAPE < 1 %), demonstrating superior predictive performance over Taguchi and regression models. Integration of the trained ANN with a Genetic Algorithm (GA) enabled global optimization of process parameters, yielding an optimum set of 85.3 A current, 7.7 m/min wire-feed speed, and 3.8 mm/s welding speed, corresponding to predicted properties of 242.5 MPa tensile strength and 108.4 HV hardness. Experimental validation confirmed deviations below 1 %, verifying the model’s robustness. The proposed ANN–GA hybrid framework effectively captures nonlinear process–structure–property relationships, providing a reliable, data-driven pathway for achieving high-strength, defect-free aluminum components in WAAM and other additive manufacturing sys-tems.

Keywords: Additive manufacturing, Gas Metal Arc Welding (GMAW), Artificial Neural Network (ANN), Genetic Algorithm (GA)

Received: November 13, 2025; Revised: March 20, 2026; Accepted: March 20, 2026; Prepublished online: March 25, 2026 

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