Assessing the Adhesiveness and Long-Term Behaviour of Piezoresistive Strain Sensor Materials for Application in Structural Health Monitored Structures

Daniel Kimpfbeck; Herbert Enser; Jonas Wagner; Lukas Heinzlmeier; Boris Buchroithner; Pavel Kulha; Bettina Heise; Günther Hannesschläger; Christoph Kralovec-Rödhammer; Martin Schagerl

doi:10.3390/s25061659

Assessing the Adhesiveness and Long-Term Behaviour of Piezoresistive Strain Sensor Materials for Application in Structural Health Monitored Structures

Daniel Kimpfbeck^*, Herbert Enser, Jonas Wagner, Lukas Heinzlmeier, Boris Buchroithner, Pavel Kulha, Bettina Heise, Günther Hannesschläger, Christoph Kralovec-Rödhammer, Martin Schagerl

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

The durability of piezoresistive sensor materials is a core prerequisite for their implementation in structural health monitoring systems. In this work, three piezoresistive materials were subjected to extensive cyclic tensile loadings, and their behaviour was analysed before, after, and during testing. To this end, aluminium specimens were coated with three different industry-grade lacquers, and then piezoresistive materials were applied onto each specimen. Sensors made from carbon black displayed excellent linearity even after tensile loading cycles (𝑅²>0.88). A decline in linearity of all sensors based on carbon allotropes was discovered, whereas the polymer-based sensors improved. Furthermore, their adhesion to the substrate is of great importance. Good adhesion ensures the strains in the underlying structure are correctly transmitted into the sensor materials. Based on contact angle measurements of liquids on sensor materials and on lacquers, their work of adhesion was determined. The findings were verified by tape adhesion tests.

Original language	English
Article number	1659
Journal	Sensors
Volume	25
Issue number	6
DOIs	https://doi.org/10.3390/s25061659
Publication status	Published - Mar 2025

Fields of science

203003 Fracture mechanics
201117 Lightweight design
203002 Endurance strength
203012 Aerospace engineering
203011 Lightweight design
205016 Materials testing
203034 Continuum mechanics
205015 Composites
203022 Technical mechanics
203 Mechanical Engineering
203007 Strength of materials
211905 Bionics
203004 Automotive technology
203015 Mechatronics
202019 High frequency engineering
502058 Digital transformation
202028 Microelectronics
202027 Mechatronics
202 Electrical Engineering, Electronics, Information Engineering
202037 Signal processing
203017 Micromechanics
202036 Sensor systems
202021 Industrial electronics

JKU Focus areas

Sustainable Development: Responsible Technologies and Management
Digital Transformation

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10.3390/s25061659Licence: CC BY

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Kimpfbeck, D., Enser, H., Wagner, J., Heinzlmeier, L., Buchroithner, B., Kulha, P., Heise, B., Hannesschläger, G., Kralovec-Rödhammer, C., & Schagerl, M. (2025). Assessing the Adhesiveness and Long-Term Behaviour of Piezoresistive Strain Sensor Materials for Application in Structural Health Monitored Structures. Sensors, 25(6), Article 1659. https://doi.org/10.3390/s25061659

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AU - Heinzlmeier, Lukas

AU - Buchroithner, Boris

AU - Kulha, Pavel

AU - Heise, Bettina

AU - Hannesschläger, Günther

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AB - The durability of piezoresistive sensor materials is a core prerequisite for their implementation in structural health monitoring systems. In this work, three piezoresistive materials were subjected to extensive cyclic tensile loadings, and their behaviour was analysed before, after, and during testing. To this end, aluminium specimens were coated with three different industry-grade lacquers, and then piezoresistive materials were applied onto each specimen. Sensors made from carbon black displayed excellent linearity even after tensile loading cycles (𝑅²>0.88). A decline in linearity of all sensors based on carbon allotropes was discovered, whereas the polymer-based sensors improved. Furthermore, their adhesion to the substrate is of great importance. Good adhesion ensures the strains in the underlying structure are correctly transmitted into the sensor materials. Based on contact angle measurements of liquids on sensor materials and on lacquers, their work of adhesion was determined. The findings were verified by tape adhesion tests.

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Assessing the Adhesiveness and Long-Term Behaviour of Piezoresistive Strain Sensor Materials for Application in Structural Health Monitored Structures

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