Development of a novel strain sensor based on fluorocarbon–elastomeric nanocomposites: Effect of network density on the electromechanical properties

Development of a novel strain sensor based on fluorocarbon–elastomeric nanocomposites: Effect of network density on the electromechanical properties

•Fluorocarbon elastomers/nanocarbon black nanocomposites were prepared by melt compounding.•Different network densities were achieved by high energy induced crosslinking.•AC and DC conductivities were found to be affected by network density.•High gauge factor was observed for the nanocomposites at o...

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Bibliographic Details
Published in:Sensors and actuators. A. Physical. 2015-01, Vol.221, p.33-40
Main Authors: Dubey, K.A., Mondal, R.K., Grover, V., Bhardwaj, Y.K., Tyagi, A.K.
Format: Article
Language:eng
Subjects:
Crosslinking
Density
Detection
FCE/NCB nanocomposite
Gages
Gauges
Nanocomposites
Nanostructure
Network
Networks
Radiation
Sensor
Sensors
Strain
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Summary:•Fluorocarbon elastomers/nanocarbon black nanocomposites were prepared by melt compounding.•Different network densities were achieved by high energy induced crosslinking.•AC and DC conductivities were found to be affected by network density.•High gauge factor was observed for the nanocomposites at optimal network density.•Cyclic electromechanical response and hysteresis were affected by network density. A fluorocarbon elastomer (FCE)/nanocarbon black (NCB) nanocomposites based strain sensor was developed and the effect of network density on the AC and DC conductivity as well as on the electromechanical performance of the sensor was investigated. Nanocomposite matrices with different network densities were achieved by irradiating with high energy radiation from Co-60 gamma source for different doses. The nanocomposite having 0.1 weight fraction of NCB showed frequency-dependent increase in the AC conductivity (σAC) over the entire frequency range (100Hz to 1MHz); whereas nanocomposite having 0.2 and 0.3 weight fractions showed no significant frequency dependence. Interestingly at 0.35 weight fraction, conductor to insulator transition took place at 0.01MHz, and a conductivity plateau was observed in 100Hz to 0.01MHz range. Network density was found to have a profound effect on the sensing range as well as on the gauge factor. Cyclic strain sensing response was also found to be affected by network density and the best results were observed for a network density of 73.2μmol/g. At higher network density (290μmol/g), two peaks were observed for each strain cycle and the sensing response was not stable. For 5 and 10% cyclic strains, gauge factor was around 14 and no change in gauge factor was observed within 2–5mm/min strain rates.
ISSN:0924-4247
1873-3069