Das, ManojitManojitDasMishra, RajatRajatMishraDas, PalashPalashDasKashyap, Sunil KumarSunil KumarKashyapPanda, Sushanta KumarSushanta KumarPandaMitra, RahulRahulMitraOwuor, Peter SamoraPeter SamoraOwuorArora, AmitAmitAroraTiwary, Chandra SekharChandra SekharTiwary2025-08-312025-08-312023-04-1210.1016/j.compscitech.2023.1099552-s2.0-85148698277http://repository.iitgn.ac.in/handle/IITG2025/26831In a 3D printed polymer composite, orientation of the reinforcement, distribution and porosity plays a major role in its mechanical properties. Here, we demonstrate a precisely control of the orientation of the reinforcement by varying different printing conditions such as nozzle diameter and flow rates. The experimental observation reveals a direct correlation between the directionality of reinforcement, porosity, and mechanical properties with printing conditions. Printed composites show an enhancement of ∼108% in tensile strength, ∼520% in toughness, and ∼188% in fracture strain as compared to film casting method. In addition, we use discrete element modeling and computational fluid dynamics numerical methodology to visualize the orientation of reinforcement inside the nozzle. The effects of controlled variables on the directionality of the reinforcement and process-property dependency are validated. These findings open new opportunities in further strengthening the mechanism by which additive manufacturing can be used to tailor the properties of polymer composites.false3D printing | Computational fluid dynamics | Discrete element modeling | Graphite | Polymer matrix composites | Regression analysisArticle12 April 202313109955arJournal15WOS:000950610900001