Data-Driven Framework for Printability and Geometric Quality Prediction in 3D Concrete Printing (2025-12)¶
, Mohomad Yosef, , Masad Eyad, Arroyave Raymundo, Tafreshi Reza
Journal Article - Materials & Design, No. 115309
Abstract
Three-dimensional concrete 3D printing (3DCP) faces persistent challenges in achieving consistent geometric quality and reproducible printability across varying process conditions, limiting its large-scale industrial adoption. This study presents a data-driven framework that integrates experimental characterization with machine learning-based prediction to evaluate and optimize geometric quality in 3DCP. Functional geometries (cubes, overhangs, and bridges) were fabricated using a robotic printing system at controlled nozzle speeds (75–150 mm/s) and flow rates (478–593 cm3/s), resulting in 46 cubes, 21 overhangs, and 66 bridges. High-resolution imaging enabled quantitative extraction of geometric indicators, including layer height variation, angle deviation, and bridge span stability, which were consolidated into a weighted geometric quality metric. Two predictive models were developed: the first estimated geometric deviations from process parameters, while the second inversely predicted optimal process parameters for a desired material response. Among several algorithms, CatBoost and DecisionTree regressors exhibited the strongest performance, with the best model achieving an of 0.74 and a mean absolute error of 1.5 mm. The derived printability map identified optimal operational regions (100–115 mm/s, 470–490 cm3/s) corresponding to stable, high-quality prints. This integrated experimental–computational approach establishes a quantitative foundation for real-time process optimization, adaptive control, and quality assurance in additive construction.
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0 Citations
BibTeX
@article{hamm_moho_shom_masa.2025.DDFfPaGQPi3CP,
author = "Ahmad Hammoud and Yosef Mohomad and Hasan Shomar and Eyad Masad and Raymundo Arroyave and Reza Tafreshi",
title = "Data-Driven Framework for Printability and Geometric Quality Prediction in 3D Concrete Printing",
doi = "10.1016/j.matdes.2025.115309",
year = "2025",
journal = "Materials & Design",
pages = "115309",
}
Formatted Citation
A. Hammoud, Y. Mohomad, H. Shomar, E. Masad, R. Arroyave and R. Tafreshi, “Data-Driven Framework for Printability and Geometric Quality Prediction in 3D Concrete Printing”, Materials & Design, p. 115309, 2025, doi: 10.1016/j.matdes.2025.115309.
Hammoud, Ahmad, Yosef Mohomad, Hasan Shomar, Eyad Masad, Raymundo Arroyave, and Reza Tafreshi. “Data-Driven Framework for Printability and Geometric Quality Prediction in 3D Concrete Printing”. Materials & Design, 2025, 115309. https://doi.org/10.1016/j.matdes.2025.115309.