Effect of strain on the properties of an ethylene-octene elastomer with conductive carbon fillers

Flandin, Lionel; Chang, Amy; Nazarenko, Sergei; Hiltner, A.; Baer, E.

doi:10.1002/(sici)1097-4628(20000509)76:6<894::aid-app16>3.0.co;2-k

Cited by 170 publications

(107 citation statements)

References 26 publications

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“…If there is a simple relationship between electrical conductivity and external variables such as temperature [3,4] and mechanical stretching [5,6], the composite has potential applications as a sensor. For these reasons, the development of new conductive composites requires an understanding of the changes in conductivity that might occur in service.…”

Section: Introductionmentioning

confidence: 99%

Effect of extensional cyclic strain on the mechanical and physico-mechanical properties of PVC-NBR/graphite composites

Mansour¹

2008

Express Polym. Lett.

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Abstract. The variation of electrical resistivity as will as the mechanical properties of PVC (polyvinylchloride)-NBR (acrylonitrile butadiene rubber) based conductive composites filled with different concentrations of graphite were studied. These samples were studied as function of the constant deformation fatigue test. When the specimen was subjected to a large number of rapidly repeating strain cycles, and different strain amplitudes, the conductivity, σ(T), shows an initial rapid fall followed by dynamic equilibrium. Increasing the number of cycles and strain amplitudes, the conductivity remains almost constant over the temperature range 30-140°C. The equilibrium state between destruction and reconstruction of graphite particles has been detected for all strains of certain values of strain cycles (1000, 2000, 3000, and 4000 cycles for 30% strain amplitude). A preliminary study was done to optimize the possibility to use Conductive Polymer Composites (CPC) as a strain sensor and to evaluate its performance by an intrinsic physico-mechanical modification measurement. The electromechanical characterization was performed to demonstrate the adaptability and the correct functioning of the sensor as a strain gauge on the fabric. The coefficient of strain sensitivity (K) was measured for 50 phr graphite/PVC-NBR vulcanized at 3000 number of strain cycles and 30% strain amplitude. There was a broad maximum of K, with a peak value of 82, which was much higher, compared to conventional wire resistors. A slight hysteresis was observed at unloading due to plasticity of the matrix. A good correlation exists between mechanical and electrical response to the strain sensitivity. Mechanical reinforcement was in accordance with the Quemada equation [1] and Guth model [2] attested to good particle-matrix adhesion. It was found that the viscous component of deformation gradually disappeared and the hardening occurred with increasing strain cycles. The modulus, fracture strength, and elongation at break increased with increasing filler volume fraction up to 40 phr of graphite particles.

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Section: Introductionmentioning

confidence: 99%

Effect of extensional cyclic strain on the mechanical and physico-mechanical properties of PVC-NBR/graphite composites

Mansour¹

2008

Express Polym. Lett.

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“…An irreversible increase has been observed in composites deformed beyond their elastic limit. 9 Many conductive composites display a positive temperature coefficient of resistance 1,2 so that at high currents the conductivity falls due to expansion and changes in morphology caused by Joule heating. However, at constant temperature composites usually display ohmic behavior.…”

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confidence: 99%

Metal–polymer composite with nanostructured filler particles and amplified physical properties

Bloor

Graham

Williams

et al. 2006

Applied Physics Letters

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“…11 The resistivity of the composite material with carbon particles above the percolation threshold can generally be modelled by the power law relation …”

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Microfabricated photoplastic cantilever with integrated photoplastic/carbon based piezoresistive strain sensor

Gammelgaard

Rasmussen

Calleja

et al. 2006

Applied Physics Letters

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We present an SU-8 micrometer sized cantilever strain sensor with an integrated piezoresistor made of a conductive composite of SU-8 polymer and carbon black particles. The composite has been developed using ultrasonic mixing. Cleanroom processing of the polymer composite has been investigated and it has been shown that it is possible to pattern the composite by standard UV photolithography. The composite material has been integrated into an SU-8 microcantilever and the polymer composite has been demonstrated to be piezoresistive with gauge factors around 15–20. Since SU-8 is much softer than silicon and the gauge factor of the composite material is relatively high, this polymer based strain sensor is more sensitive than a similar silicon based cantilever sensor.

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Effect of strain on the properties of an ethylene-octene elastomer with conductive carbon fillers

Cited by 170 publications

References 26 publications

Effect of extensional cyclic strain on the mechanical and physico-mechanical properties of PVC-NBR/graphite composites

Effect of extensional cyclic strain on the mechanical and physico-mechanical properties of PVC-NBR/graphite composites

Metal–polymer composite with nanostructured filler particles and amplified physical properties

Microfabricated photoplastic cantilever with integrated photoplastic/carbon based piezoresistive strain sensor

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