Fully integrated carbon nanotube composite thin film strain sensors on flexible substrates for structural health monitoring

Burton, Andrew; Lynch, Jerome P.; Kurata, Masahiro; Law, Kincho H.

doi:10.1088/1361-665x/aa8105

Cited by 25 publications

(15 citation statements)

References 43 publications

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“…Strain-based methods coupled with thin-film sensors have shown potential for continuous detection and monitoring of fatigue cracks over large-scale structural surfaces (Burton et al 2017;Loh et al 2007a;Loh et al 2009). The methodology is aimed at capturing abrupt strain change induced by cracking in the local region by deploying large-area strain sensors over fatigue-susceptible regions of structural components.…”

Section: Introductionmentioning

confidence: 99%

Thin-Film Sensor for Fatigue Crack Sensing and Monitoring in Steel Bridges under Varying Crack Propagation Rates and Random Traffic Loads

Kong

Bennett

et al. 2019

J. Aerosp. Eng.

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Fatigue cracks are critical structural concerns for steel highway bridges, and fatigue initiation and propagation activity continues undetected between physical bridge inspections. Monitoring fatigue crack activity between physical inspections can provide far greater reliability in structural performance and can be used to prevent excessive damage and repair costs. In this paper, a thin-film strain sensor, called a soft elastomeric capacitor (SEC) sensor, is evaluated for sensing and monitoring fatigue cracks in steel bridges. The SEC is a flexible and mechanically robust strain sensor, capable of monitoring strain over large structural surfaces. By deploying multiple SECs in the form of dense sensor arrays, it is possible to detect fatigue cracks over large regions of a structural member such as a bridge girder. Previous studies have verified the SEC's capability to monitor fatigue cracks under idealized harmonic load cycles with a constant crack propagation rate. Here, an investigation is performed under more complex and realistic situations to translate the SEC technology from laboratory testing to field applications-specifically, as cracking propagates under (1) a decreasing crack propagation rate, and (2) random traffic load cycles with stochastic peak-to-peak amplitudes and periods. An experimental program was developed which included an efficient data collection strategy, new loading protocols, and crack-sensing algorithms. The experimental results showed an increasing trend of the fatigue damage feature, crack growth index (CGI), under crack initiation and propagation, despite decreasing crack propagation rates or random traffic load cycles. In addition, the results also showed that the SEC did not produce false-positive results when cracks stopped growing. The findings of this study significantly enhance the SEC's fatigue sensing and monitoring capability under more realistic loading conditions, which is a critical step toward field applications of this technology.

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Section: Introductionmentioning

confidence: 99%

Thin-Film Sensor for Fatigue Crack Sensing and Monitoring in Steel Bridges under Varying Crack Propagation Rates and Random Traffic Loads

Kong

Bennett

et al. 2019

J. Aerosp. Eng.

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“…Therefore, it is mostly used to measure one-dimensional stress and strain in concrete. Polymer-based intelligent sensor [15,16] can avoid the above problems, because of the good corrosion resistance and waterproofing, simple molding, and well plasticity of polymer materials.…”

Section: Introductionmentioning

confidence: 99%

A Three-Dimensional Strain Rosette Sensor Based on Graphene Composite with Piezoresistive Effect

Wei

Dong

et al. 2019

Journal of Sensors

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Obtaining the internal stress and strain state of concrete to evaluate the safety and reliability of structures is the important purpose of concrete structural health monitoring. In this paper, a three-dimensional (3D) strain rosette sensor was designed and fabricated using graphene-based piezoresistive composite to measure the strains in concrete structures. The piezoresistive composite was prepared using reduced graphene oxide (RGO) as conductive filler, cellulose nanofiber (CNF) as dispersant and structural skeleton, and waterborne epoxy (WEP) as polymer matrix. The mechanical, electrical, and electromechanical properties of RGO-CNF/WEP composite were tested. The results show that the tensile strength, elastic modulus, and conductivity of the composite are greatly improved by the addition of RGO and CNF. The relative resistance change of composite films demonstrates high sensitivity to mechanical strain with gauge factors of 16-52. Within 4% strain, the piezoresistive properties of composites are stable with good linearity and repeatability. The sensing performance of the 3D strain rosette was tested. The measured strains are close to the actual strains of measure point in concrete, and the error is small. The RGO-CNF/WEP composite has excellent mechanical and piezoresistive properties, which enable the 3D strain rosette to be used as embedded sensor to measure the internal strain of concrete structures accurately.

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“…[1][2][3][4][5] Of particular interest is the monitoring of wind turbine systems operating in either offshore 6 or remote environments 7 where maintenance and operation costs may be from two to five times higher than for in-land systems. These smart materials have the potential to greatly improve the functionality of fully integrated SHM systems deployed on wind turbines.…”

Section: Introductionmentioning

confidence: 99%

“…Potential benefits provided by these smart materials include reduced manufacturing and installation costs, 8 large area sensing capabilities 2 and fully integrated electronics. 3 Another unique feature of these smart materials is the capability to both cover large areas and, when deployed in a dense sensor network, distinguish local from global damages. 5,9 However, due to the novelty of these sensing technologies, the effect of environmental conditions on this new class of smart materials has not been sufficiently addressed.…”

Section: Introductionmentioning

confidence: 99%

Durability assessment of soft elastomeric capacitor skin for SHM of wind turbine blades

Downey

Pisello

Fortunati

et al. 2018

Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XII

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Renewable energy production has become a key research driver during the last decade. Wind energy represents a ready technology for large-scale implementation in locations all around the world. While important research is conducted to optimize wind energy production efficiency, a critical issue consists of monitoring the structural integrity and functionality of these large structures during their operational life cycle. This paper investigates the durability of a soft elastomeric capacitor strain sensing membrane, designed for structural health monitoring of wind turbines, when exposed to aggressive environmental conditions. The sensor is a capacitor made of three thin layers of an SEBS polymer in a sandwich configuration. The inner layer is doped with titania and acts as the dielectric, while the external layers are filled with carbon black and work as the conductive plates. Here, a variety of samples, not limited to the sensor configuration but also including its dielectric layer, were fabricated and tested within an accelerated weathering chamber (QUV) by simulating thermal, humidity, and UV radiation cycles. A variety of other tests were performed in order to characterize their mechanical, thermal, and electrical performance in addition to their solar reflectance. These tests were carried out before and after the QUV exposures of 1, 7, 15, and 30 days. The tests showed that titania inclusions improved the sensor durability against weathering. These findings contribute to better understanding the field behavior of these skin sensors, while future developments will concern the analysis of the sensing properties of the skin after aging. KeywordsSoft elastomeric capacitor, structural health monitoring, durability, titania, titanium dioxide, TiO2, weatherability, environmental degradation ABSTRACTRenewable energy production has become a key research driver during the last decade. Wind energy represents a ready technology for large-scale implementation in locations all around the world. While important research is conducted to optimize wind energy production efficiency, a critical issue consists of monitoring the structural integrity and functionality of these large structures during their operational life cycle. This paper investigates the durability of a soft elastomeric capacitor strain sensing membrane, designed for structural health monitoring of wind turbines, when exposed to aggressive environmental conditions. The sensor is a capacitor made of three thin layers of an SEBS polymer in a sandwich configuration. The inner layer is doped with titania and acts as the dielectric, while the external layers are filled with carbon black and work as the conductive plates. Here, a variety of samples, not limited to the sensor configuration but also including its dielectric layer, were fabricated and tested within an accelerated weathering chamber (QUV) by simulating thermal, humidity, and UV radiation cycles. A variety of other tests were performed in order to characterize their mechanical, thermal, and elect...

show abstract

Fully integrated carbon nanotube composite thin film strain sensors on flexible substrates for structural health monitoring

Cited by 25 publications

References 43 publications

Thin-Film Sensor for Fatigue Crack Sensing and Monitoring in Steel Bridges under Varying Crack Propagation Rates and Random Traffic Loads

Thin-Film Sensor for Fatigue Crack Sensing and Monitoring in Steel Bridges under Varying Crack Propagation Rates and Random Traffic Loads

A Three-Dimensional Strain Rosette Sensor Based on Graphene Composite with Piezoresistive Effect

Durability assessment of soft elastomeric capacitor skin for SHM of wind turbine blades

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