In-silico Platform for the Multifunctional Design of 3D Printed Conductive Components

Overview

Journal Nat Commun

Date 2025 Feb 5

PMID 39905061

Authors

Javier Crespo-Miguel

Sergio Lucarini

Sara Garzon-Hernandez

Angel Arias

Emilio Martinez-Paneda

Daniel Garcia-Gonzalez

Affiliations

Soon will be listed here.

Abstract

The effective electric resistivity of conductive thermoplastics manufactured by filament extrusion methods is determined by both the material constituents and the printing parameters. The former determines the multifunctional nature of the composite, whereas the latter dictates the mesostructural characteristics such as filament adhesion and void distribution. This work provides a multi-scale computational framework to evaluate the thermo-electro-mechanical behaviour of printed conductive polymers. A full-field homogenisation model first provides the influence of material and mesostructural features (i.e., filament orientations, voids and adhesion between filaments). Then, a macroscopic continuum model elucidates the effects of thermo-electro-mechanical mixed boundary conditions. The in-silico multi-scale methodology is validated with extensive original multi-physical experiments and a functional application consisting of an electro-heatable printing cartridge. Overall, this work establishes the foundations to virtually break the gap between mesoscopic and macroscopic multifunctional responses in conductive components manufactured by additive manufacturing techniques.

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