Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies

Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies

This paper presents a parametric study of classical additive 3D-printing settings for use on conductive filaments in applications for high-frequency topologies. First, a wideband characterization was conducted, printing a microstrip transmission line using a conductive filament with variations of ty...

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Main Authors: Francisco Pizarro, Rolando Salazar, Eva Rajo-Iglesias, Mauricio Rodriguez, Sebastian Fingerhuth, Gabriel Hermosilla
Format: Article
Language:English
Published: IEEE 2019-01-01
Series:IEEE Access
Subjects:
3D-printing
wideband characterization
3D-printed antennas
conductive PLA
Online Access:https://ieeexplore.ieee.org/document/8786183/
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spelling doaj-bc945c78d0804e14b6068246702ed78a2021-04-05T17:03:48ZengIEEEIEEE Access2169-35362019-01-01710681410682310.1109/ACCESS.2019.29329128786183Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave TopologiesFrancisco Pizarro0https://orcid.org/0000-0003-0516-4736Rolando Salazar1Eva Rajo-Iglesias2Mauricio Rodriguez3Sebastian Fingerhuth4Gabriel Hermosilla5Escuela de Ingenieria Eléctrica, Pontificia Universidad Católica de Valparaíso, Valparaíso, ChileEscuela de Ingenieria Eléctrica, Pontificia Universidad Católica de Valparaíso, Valparaíso, ChileDepartment of Signal Theory and Communication, University Carlos III of Madrid, Madrid, SpainEscuela de Ingenieria Eléctrica, Pontificia Universidad Católica de Valparaíso, Valparaíso, ChileEscuela de Ingenieria Eléctrica, Pontificia Universidad Católica de Valparaíso, Valparaíso, ChileEscuela de Ingenieria Eléctrica, Pontificia Universidad Católica de Valparaíso, Valparaíso, ChileThis paper presents a parametric study of classical additive 3D-printing settings for use on conductive filaments in applications for high-frequency topologies. First, a wideband characterization was conducted, printing a microstrip transmission line using a conductive filament with variations of typical 3D-printing settings, such as layer height, infill percentage, and infill pattern. The measurement results show a dependence on the high-frequency transmission parameters with respect to the infill percentage and the infill pattern. Finally, two antennas were 3D-printed using conductive material, a microstrip patch, and a low-weight pyramidal horn antenna. The results for the patch agree with the losses found on the line measurements, while the low-weight pyramidal horn exhibits no major differences compared with its equivalent antenna, made using perfect conductors.https://ieeexplore.ieee.org/document/8786183/3D-printingwideband characterization3D-printed antennasconductive PLA
collection DOAJ
language English
format Article
sources DOAJ
author Francisco Pizarro
Rolando Salazar
Eva Rajo-Iglesias
Mauricio Rodriguez
Sebastian Fingerhuth
Gabriel Hermosilla
spellingShingle Francisco Pizarro
Rolando Salazar
Eva Rajo-Iglesias
Mauricio Rodriguez
Sebastian Fingerhuth
Gabriel Hermosilla
Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies
IEEE Access
3D-printing
wideband characterization
3D-printed antennas
conductive PLA
author_facet Francisco Pizarro
Rolando Salazar
Eva Rajo-Iglesias
Mauricio Rodriguez
Sebastian Fingerhuth
Gabriel Hermosilla
author_sort Francisco Pizarro
title Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies
title_short Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies
title_full Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies
title_fullStr Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies
title_full_unstemmed Parametric Study of 3D Additive Printing Parameters Using Conductive Filaments on Microwave Topologies
title_sort parametric study of 3d additive printing parameters using conductive filaments on microwave topologies
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2019-01-01
description This paper presents a parametric study of classical additive 3D-printing settings for use on conductive filaments in applications for high-frequency topologies. First, a wideband characterization was conducted, printing a microstrip transmission line using a conductive filament with variations of typical 3D-printing settings, such as layer height, infill percentage, and infill pattern. The measurement results show a dependence on the high-frequency transmission parameters with respect to the infill percentage and the infill pattern. Finally, two antennas were 3D-printed using conductive material, a microstrip patch, and a low-weight pyramidal horn antenna. The results for the patch agree with the losses found on the line measurements, while the low-weight pyramidal horn exhibits no major differences compared with its equivalent antenna, made using perfect conductors.
topic 3D-printing
wideband characterization
3D-printed antennas
conductive PLA
url https://ieeexplore.ieee.org/document/8786183/
work_keys_str_mv AT franciscopizarro parametricstudyof3dadditiveprintingparametersusingconductivefilamentsonmicrowavetopologies
AT rolandosalazar parametricstudyof3dadditiveprintingparametersusingconductivefilamentsonmicrowavetopologies
AT evarajoiglesias parametricstudyof3dadditiveprintingparametersusingconductivefilamentsonmicrowavetopologies
AT mauriciorodriguez parametricstudyof3dadditiveprintingparametersusingconductivefilamentsonmicrowavetopologies
AT sebastianfingerhuth parametricstudyof3dadditiveprintingparametersusingconductivefilamentsonmicrowavetopologies
AT gabrielhermosilla parametricstudyof3dadditiveprintingparametersusingconductivefilamentsonmicrowavetopologies
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