3D-Printed Conductance-Based Force Sensors Using Single Traxels

Anders Frem Wolstrup; Thomas Schlaikjer Holst; Jon Spangenberg; Tiberiu Gabriel Zsurzsan

doi:10.1109/LSENS.2025.3571198

3D-Printed Conductance-Based Force Sensors Using Single Traxels

Anders Frem Wolstrup^*, Thomas Schlaikjer Holst, Jon Spangenberg, Tiberiu Gabriel Zsurzsan

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

This study investigates the use of 3D printing for fabricating conductance-based force sensors with cellbased geometries. Three mathematically defined structures, sine wave, circle, and Reuleaux triangle, were implemented using single traxels (3D-printed conductive tracks) to maximize contact area and enabling consistent fabrication. The sensors were produced via Fused Deposition Modelling (FDM) and programmed using FullControl G-code, enabling direct translation of mathematical functions into print paths. The sine wave design achieved the highest sensitivity (0.035 N⁻¹) and 95% linearity, consistent with constriction resistance theory. All designs demonstrated reliable performance with minimal process-induced variation. These findings highlight the potential of traxel-based 3D printing as a cost-effective and customizable approach for producing force sensors suited for applications in human-machine interfacing and soft robotics.

Original language	English
Article number	2502404
Journal	IEEE Sensors Letters
Volume	9
Issue number	7
Number of pages	4
ISSN	2475-1472
DOIs	https://doi.org/10.1109/LSENS.2025.3571198
Publication status	Published - 2025

Keywords

3D-printed sensors
Additive manufacturing
Constriction resistance
Contact resistance

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10.1109/LSENS.2025.3571198

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title = "3D-Printed Conductance-Based Force Sensors Using Single Traxels",

abstract = "This study investigates the use of 3D printing for fabricating conductance-based force sensors with cellbased geometries. Three mathematically defined structures, sine wave, circle, and Reuleaux triangle, were implemented using single traxels (3D-printed conductive tracks) to maximize contact area and enabling consistent fabrication. The sensors were produced via Fused Deposition Modelling (FDM) and programmed using FullControl G-code, enabling direct translation of mathematical functions into print paths. The sine wave design achieved the highest sensitivity (0.035 N−1) and 95\% linearity, consistent with constriction resistance theory. All designs demonstrated reliable performance with minimal process-induced variation. These findings highlight the potential of traxel-based 3D printing as a cost-effective and customizable approach for producing force sensors suited for applications in human-machine interfacing and soft robotics.",

keywords = "3D-printed sensors, Additive manufacturing, Constriction resistance, Contact resistance",

author = "Wolstrup, \{Anders Frem\} and Holst, \{Thomas Schlaikjer\} and Jon Spangenberg and Zsurzsan, \{Tiberiu Gabriel\}",

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year = "2025",

doi = "10.1109/LSENS.2025.3571198",

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PY - 2025

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AB - This study investigates the use of 3D printing for fabricating conductance-based force sensors with cellbased geometries. Three mathematically defined structures, sine wave, circle, and Reuleaux triangle, were implemented using single traxels (3D-printed conductive tracks) to maximize contact area and enabling consistent fabrication. The sensors were produced via Fused Deposition Modelling (FDM) and programmed using FullControl G-code, enabling direct translation of mathematical functions into print paths. The sine wave design achieved the highest sensitivity (0.035 N−1) and 95% linearity, consistent with constriction resistance theory. All designs demonstrated reliable performance with minimal process-induced variation. These findings highlight the potential of traxel-based 3D printing as a cost-effective and customizable approach for producing force sensors suited for applications in human-machine interfacing and soft robotics.

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KW - Constriction resistance

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DO - 10.1109/LSENS.2025.3571198

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3D-Printed Conductance-Based Force Sensors Using Single Traxels

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