Modelling of the electromechanical impedance technique for prediction of elastic modulus of structural adhesives

Tang, Zi Sheng, Lim, Yee Yan, Smith, Scott T., and Padilla, Ricardo Vasquez (2021) Modelling of the electromechanical impedance technique for prediction of elastic modulus of structural adhesives. Structural Health Monitoring, 20 (5). pp. 2245-2260.

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Abstract

In order to strengthen and repair existing concrete structural elements, fibre-reinforced polymer composites are often externally bonded using structural adhesives. It is thus desirable to monitor the in situ performance of the sandwiched adhesive layer in such fibre-reinforced polymer–strengthened systems via its stiffness and strength gain throughout the curing process. The electromechanical impedance technique, which relies upon the utilisation of piezoelectric sensors, offers this capability. Although the technique has been verified experimentally in the laboratory, no known electromechanical impedance–based modelling study has been reported. This study, therefore, proposes the first electromechanical impedance–based finite element and analytical models to monitor the curing of structural adhesives. The dynamic elastic modulus of structural adhesives during curing can be determined from the developed models via a model updating process. Semi-empirical relationships were then developed to determine the tensile strength of structural adhesives from the resonance frequency obtained from the electromechanical impedance technique. This was made possible by correlation between static tensile tests on structural adhesives and the dynamic elastic modulus. These electromechanical impedance–based models were found to perform equally well when compared to the previously developed wave propagation–based models. This study shows the robustness of the electromechanical impedance technique for non-destructively predicting the dynamic elastic modulus and tensile strength of adhesives throughout the curing process.

Item ID: 80951
Item Type: Article (Research - C1)
ISSN: 1741-3168
Keywords: Adhesive, curing, electromechanical impedance technique, finite element method, lead zirconate titanate, modelling
Copyright Information: © The Author(s) 2020.
Date Deposited: 07 Nov 2023 00:26
FoR Codes: 40 ENGINEERING > 4005 Civil engineering > 400509 Structural dynamics @ 50%
40 ENGINEERING > 4099 Other engineering > 409902 Engineering instrumentation @ 50%
SEO Codes: 12 CONSTRUCTION > 1203 Construction materials performance and processes > 120399 Construction materials performance and processes not elsewhere classified @ 100%
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