Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications

Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications

As the usage of wireless technology grows, it demands more complex architectures and conformal geometries, making the manufacturing of radio frequency (RF) systems challenging and expensive. The incorporation of emerging alternative manufacturing technologies, like additive manufacturing (AM), could...

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Bibliographic Details
Main Authors: Dipankar Mitra, Sayan Roy, Ryan Striker, Ellie Burczek, Ahsan Aqueeb, Henry Wolf, Kazi Sadman Kabir, Shengrong Ye, Benjamin D. Braaten
Format: Article
Language:English
Published: MDPI AG 2021-03-01
Series:Electronics
Subjects:
additive manufacturing
conformal antenna
<i>Electrifi</i>
<i>NinjaFlex</i>
flexible antenna
Online Access:https://www.mdpi.com/2079-9292/10/7/821
id doaj-60e64c70f48c4ea8a87e2cd464b38aac
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spelling doaj-60e64c70f48c4ea8a87e2cd464b38aac2021-03-30T23:05:40ZengMDPI AGElectronics2079-92922021-03-011082182110.3390/electronics10070821Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface ApplicationsDipankar Mitra0Sayan Roy1Ryan Striker2Ellie Burczek3Ahsan Aqueeb4Henry Wolf5Kazi Sadman Kabir6Shengrong Ye7Benjamin D. Braaten8Department of Electrical and Computer Engineering, North Dakota State University, Fargo, ND 58102, USADepartment of Electrical Engineering, South Dakota School of Mines & Technology, Rapid City, SD 57701, USADepartment of Electrical and Computer Engineering, North Dakota State University, Fargo, ND 58102, USADepartment of Electrical Engineering, South Dakota School of Mines & Technology, Rapid City, SD 57701, USADepartment of Electrical Engineering, South Dakota School of Mines & Technology, Rapid City, SD 57701, USADepartment of Electrical and Computer Engineering, North Dakota State University, Fargo, ND 58102, USADepartment of Electrical Engineering and Computer Science, University of Toledo, Toledo, OH 43606, USAMulti3D Inc., Cary, NC 27751, USADepartment of Electrical and Computer Engineering, North Dakota State University, Fargo, ND 58102, USAAs the usage of wireless technology grows, it demands more complex architectures and conformal geometries, making the manufacturing of radio frequency (RF) systems challenging and expensive. The incorporation of emerging alternative manufacturing technologies, like additive manufacturing (AM), could consequently be a unique and cost-effective solution for flexible RF and microwave circuits and devices. This work presents manufacturing methodologies of 3D-printed conformal microstrip antennas made of a commercially available conductive filament, <i>Electrifi</i>, as the conductive trace on a commercially available nonconductive filament, <i>NinjaFlex</i>, as the substrate using the fused filament fabrication (FFF) method of AM technology. Additionally, a complete high frequency characterization of the prototyped antenna was studied and presented here through a comparative analysis between full-wave simulation and measurements in a fully calibrated anechoic chamber. The prototyped antenna measures 65.55 × 55.55 × 1.2 mm<sup>3</sup> in size and the measured results show that the 3D-printed <i>Electrifi </i>based patch antenna achieved very good impedance matching at a resonant frequency of 2.4 GHz and a maximum antenna gain of −2.78 dBi. Finally, conformality performances of the developed antenna were demonstrated by placing the antenna prototype on five different cylindrical curved surfaces for possible implementation in flexible electronics, smart communications, and radar applications.https://www.mdpi.com/2079-9292/10/7/821additive manufacturingconformal antenna<i>Electrifi</i><i>NinjaFlex</i>flexible antenna
collection DOAJ
language English
format Article
sources DOAJ
author Dipankar Mitra
Sayan Roy
Ryan Striker
Ellie Burczek
Ahsan Aqueeb
Henry Wolf
Kazi Sadman Kabir
Shengrong Ye
Benjamin D. Braaten
spellingShingle Dipankar Mitra
Sayan Roy
Ryan Striker
Ellie Burczek
Ahsan Aqueeb
Henry Wolf
Kazi Sadman Kabir
Shengrong Ye
Benjamin D. Braaten
Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications
Electronics
additive manufacturing
conformal antenna
<i>Electrifi</i>
<i>NinjaFlex</i>
flexible antenna
author_facet Dipankar Mitra
Sayan Roy
Ryan Striker
Ellie Burczek
Ahsan Aqueeb
Henry Wolf
Kazi Sadman Kabir
Shengrong Ye
Benjamin D. Braaten
author_sort Dipankar Mitra
title Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications
title_short Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications
title_full Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications
title_fullStr Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications
title_full_unstemmed Conductive <i>Electrifi</i> and Nonconductive <i>NinjaFlex</i> Filaments based Flexible Microstrip Antenna for Changing Conformal Surface Applications
title_sort conductive <i>electrifi</i> and nonconductive <i>ninjaflex</i> filaments based flexible microstrip antenna for changing conformal surface applications
publisher MDPI AG
series Electronics
issn 2079-9292
publishDate 2021-03-01
description As the usage of wireless technology grows, it demands more complex architectures and conformal geometries, making the manufacturing of radio frequency (RF) systems challenging and expensive. The incorporation of emerging alternative manufacturing technologies, like additive manufacturing (AM), could consequently be a unique and cost-effective solution for flexible RF and microwave circuits and devices. This work presents manufacturing methodologies of 3D-printed conformal microstrip antennas made of a commercially available conductive filament, <i>Electrifi</i>, as the conductive trace on a commercially available nonconductive filament, <i>NinjaFlex</i>, as the substrate using the fused filament fabrication (FFF) method of AM technology. Additionally, a complete high frequency characterization of the prototyped antenna was studied and presented here through a comparative analysis between full-wave simulation and measurements in a fully calibrated anechoic chamber. The prototyped antenna measures 65.55 × 55.55 × 1.2 mm<sup>3</sup> in size and the measured results show that the 3D-printed <i>Electrifi </i>based patch antenna achieved very good impedance matching at a resonant frequency of 2.4 GHz and a maximum antenna gain of −2.78 dBi. Finally, conformality performances of the developed antenna were demonstrated by placing the antenna prototype on five different cylindrical curved surfaces for possible implementation in flexible electronics, smart communications, and radar applications.
topic additive manufacturing
conformal antenna
<i>Electrifi</i>
<i>NinjaFlex</i>
flexible antenna
url https://www.mdpi.com/2079-9292/10/7/821
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