Integrity-Sensing Based on Surface Roughness of Copper Conductors for Future Use in Natural Fiber Composites

Copper shows the remarkable behavior of the formation of surface roughness under mechanical strain, which creates the opportunity for its use as a sensing element. A copper-based sensor, which is intended for integration into natural fiber composites, can provide information about the remaining serv...

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Veröffentlicht in:	IEEE sensors letters 2021-03, Vol.5 (3), p.1-4
Hauptverfasser:	Baron, Philipp, Lenz, Philipp, Wittmann, Armin, Fischer, Georg
Format:	Artikel
Sprache:	eng
Schlagworte:	Bending Composite materials Conductors Copper Fiber composites line sensor Mechanical properties Mechanical sensors natural fiber composite material Rough surfaces Sensors Service life Stress Stress-strain curves Stress-strain relationships Structural integrity Surface roughness
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creator	Baron, Philipp Lenz, Philipp Wittmann, Armin Fischer, Georg
description	Copper shows the remarkable behavior of the formation of surface roughness under mechanical strain, which creates the opportunity for its use as a sensing element. A copper-based sensor, which is intended for integration into natural fiber composites, can provide information about the remaining service life of the composite material and, thus, monitor the component's structural integrity. In this letter, proof is provided that the mechanical strains tension/compression, bending and torsion generate surface roughness on copper conductors. To verify this thesis, roughness is generated in different standardized test setups. Measurements of the root mean square height S q verify that all relevant forms of mechanical forces lead to increased surface roughness. Furthermore, two methods are presented, which allow us to vary the sensitivity of the copper conductor to mechanical stress. The changes in mechanical properties are visualized with a stress-strain diagram. By providing evidence for the chain of reasoning, this article gives a qualitative proof for the feasibility of a "line sensor."
doi_str_mv	10.1109/LSENS.2021.3061143
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A copper-based sensor, which is intended for integration into natural fiber composites, can provide information about the remaining service life of the composite material and, thus, monitor the component's structural integrity. In this letter, proof is provided that the mechanical strains tension/compression, bending and torsion generate surface roughness on copper conductors. To verify this thesis, roughness is generated in different standardized test setups. Measurements of the root mean square height S q verify that all relevant forms of mechanical forces lead to increased surface roughness. Furthermore, two methods are presented, which allow us to vary the sensitivity of the copper conductor to mechanical stress. The changes in mechanical properties are visualized with a stress-strain diagram. 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subjects	Bending Composite materials Conductors Copper Fiber composites line sensor Mechanical properties Mechanical sensors natural fiber composite material Rough surfaces Sensors Service life Stress Stress-strain curves Stress-strain relationships Structural integrity Surface roughness
title	Integrity-Sensing Based on Surface Roughness of Copper Conductors for Future Use in Natural Fiber Composites
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