Exploring the potential of in-situ foam 3D printing: Effects of printing parameters and the development of functionally graded foams

Exploring the potential of in-situ foam 3D printing: Effects of printing parameters and the development of functionally graded foams

In this study, we investigated the influence of processing parameters on the cellular structure and density of specimens fabricated using in-situ foam 3D printing. First, we conducted a comprehensive analysis to examine how the combined effects of printing temperature and speed influence the four ke...

Full description

Saved in:
Bibliographic Details
Main Authors: Viktória Kunsági, Péter Széplaki, Márton Tomin
Format: Article
Language:English
Published: Budapest University of Technology and Economics 2025-07-01
Series:eXPRESS Polymer Letters
Subjects:
biopolymer foams
closed-cell foams
foam
porosity
scanning electron microscopy
advanced foam applications
dynamic testing
image processing
static testing
Online Access:https://www.expresspolymlett.com/article.php?a=EPL-0013310
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In this study, we investigated the influence of processing parameters on the cellular structure and density of specimens fabricated using in-situ foam 3D printing. First, we conducted a comprehensive analysis to examine how the combined effects of printing temperature and speed influence the four key stages of the foaming process: gas dissolution, cell nucleation, cell growth, and stabilization. By evaluating the structural characteristics of the printed foams, we identified the dominant mechanisms governing each stage. Next, we explored the effect of nozzle diameter, an aspect previously unexamined in the literature. We found that smaller nozzle diameters promote higher cell density due to enhanced pressure drop and shear-induced nucleation, resulting in a 36.78% reduction in density and a 60.31% increase in cell density when using a 0.4 mm nozzle instead of 0.8 mm (at 240°C, 60 mm/sec). Finally, we fabricated functionally graded four-layer structures by adjusting the printing temperature for each layer to control porosity distribution. To evaluate the mechanical performance of these graded structures, we performed three-point bending and drop-weight impact tests, allowing us to assess how layer order influences mechanical properties. Our results showed that proper layer sequencing can increase flexural strength by up to 69.35% and improve perforation energy by more than 94.82% compared to homogeneous structures.
ISSN:1788-618X

Similar Items