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Numerical study for the improvement of bead spreading architecture with modified nozzle geometries in additive manufacturing of polymers

Easir Arafat Papon (Department of Aerospace Engineering and Mechanics, University of Alabama, Tuscaloosa, Alabama, USA)
Anwarul Haque (Department of Aerospace Engineering and Mechanics, University of Alabama, Tuscaloosa, Alabama, USA)
Muhammad Ali Rob Sharif (Department of Aerospace Engineering and Mechanics, University of Alabama, Tuscaloosa, Alabama, USA)

Rapid Prototyping Journal

ISSN: 1355-2546

Article publication date: 4 February 2021

Issue publication date: 2 April 2021

677

Abstract

Purpose

This paper aims to develop a numerical model of bead spreading architecture of a viscous polymer in fused filament fabrication (FFF) process with different nozzle geometry. This paper also focuses on the manufacturing feasibility of the nozzles and 3D printing of the molten beads using the developed nozzles.

Design/methodology/approach

The flow of a highly viscous polymer from a nozzle, the melt expansion in free space and the deposition of the melt on a moving platform are captured using the FLUENT volume of fluid (VOF) method based computational fluid dynamics code. The free surface motion of the material is captured in VOF, which is governed by the hydrodynamics of the two-phase flow. The phases involved in the numerical model are liquid polymer and air. A laminar, non-Newtonian and non-isothermal flow is assumed. Under such assumptions, the spreading characteristic of the polymer is simulated with different nozzle-exit geometries. The governing equations are solved on a regular stationary grid following a transient algorithm, where the boundary between the polymer and the air is tracked by piecewise linear interface construction (PLIC) to reconstruct the free surface. The prototype nozzles were also manufactured, and the deposition of the molten beads on a flatbed was performed using a commercial 3D printer. The deposited bead cross-sections were examined through optical microscopic examination, and the cross-sectional profiles were compared with those obtained in the numerical simulations.

Findings

The numerical model successfully predicted the spreading characteristics and the cross-sectional shape of the extruded bead. The cross-sectional shape of the bead varied from elliptical (with circular nozzle) to trapezoidal (with square and star nozzles) where the top and bottom surfaces are significantly flattened (which is desirable to reduce the void spaces in the cross-section). The numerical model yielded a good approximation of the bead cross-section, capturing most of the geometric features of the bead with a reasonable qualitative agreement compared to the experiment. The quantitative comparison of the cross-sectional profiles against experimental observation also indicated a favorable agreement. The significant improvement observed in the bead cross-section with the square and star nozzles is the flattening of the surfaces.

Originality/value

The developed numerical algorithm attempts to address the fundamental challenge of voids and bonding in the FFF process. It presents a new approach to increase the inter-bead bonding and reduce the inter-bead voids in 3D printing of polymers by modifying the bead cross-sectional shape through the modification of nozzle exit-geometry. The change in bead cross-sectional shape from elliptical (circular) to trapezoidal (square and star) cross-section is supposed to increase the contact surface area and inter-bead bonding while in contact with adjacent beads.

Keywords

Acknowledgements

The authors would like to acknowledge the assistance of Dr Raphael Comminal from the Technical University of Denmark for his thoughtful insight in developing the numerical model. The assistance of UA Machine Shop in manufacturing the nozzles and Society of Plastic Engineers (SPE) Education Grant (#26708) from SPE Composites Division in purchasing the single screw extruder is also acknowledged.

Citation

Papon, E.A., Haque, A. and Sharif, M.A.R. (2021), "Numerical study for the improvement of bead spreading architecture with modified nozzle geometries in additive manufacturing of polymers", Rapid Prototyping Journal, Vol. 27 No. 3, pp. 518-529. https://doi.org/10.1108/RPJ-05-2019-0142

Publisher

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Emerald Publishing Limited

Copyright © 2021, Emerald Publishing Limited

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