Thermoplastic vulcanizate nanocomposites based on polyethylene/reclaimed rubber: A correlation between carbon nanotube dispersion state and electrical percolation threshold

Vahidifar, Ali; Esmizadeh, Elnaz; Elahi, Maryam; Ghoreishy, Mir Hamid Reza; Naderi, Ghasem; Rodrigue, Denis

doi:10.1002/app.47795

Cited by 16 publications

(15 citation statements)

References 46 publications

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“…Since all polymers have electrical insulating properties, various electrically conductive fillers such as CB, exfoliated graphite, CNF or CNT are added to convert them to composites for antistatic and EMI shielding applications [ 268 , 269 , 270 , 271 , 272 , 273 , 274 ]. However, the presence of these fillers alone cannot induce electrical properties, and their uniform dispersion inside polymer matrices is one of the most promising methods to reduce the percolation threshold [ 275 ]. This critical filler content is related to a several orders of magnitude variation in electrical conductivity due to the formation of continuous electron paths or conducting networks [ 276 ].…”

Section: Properties Of Rubber Foamsmentioning

confidence: 99%

Chemistry, Processing, Properties, and Applications of Rubber Foams

Rostami‐Tapeh‐Esmaeil

Vahidifar

Esmizadeh

et al. 2021

Polymers

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With the ever-increasing development in science and technology, as well as social awareness, more requirements are imposed on the production and property of all materials, especially polymeric foams. In particular, rubber foams, compared to thermoplastic foams in general, have higher flexibility, resistance to abrasion, energy absorption capabilities, strength-to-weight ratio and tensile strength leading to their widespread use in several applications such as thermal insulation, energy absorption, pressure sensors, absorbents, etc. To control the rubber foams microstructure leading to excellent physical and mechanical properties, two types of parameters play important roles. The first category is related to formulation including the rubber (type and grade), as well as the type and content of accelerators, fillers, and foaming agents. The second category is associated to processing parameters such as the processing method (injection, extrusion, compression, etc.), as well as different conditions related to foaming (temperature, pressure and number of stage) and curing (temperature, time and precuring time). This review presents the different parameters involved and discusses their effect on the morphological, physical, and mechanical properties of rubber foams. Although several studies have been published on rubber foams, very few papers reviewed the subject and compared the results available. In this review, the most recent works on rubber foams have been collected to provide a general overview on different types of rubber foams from their preparation to their final application. Detailed information on formulation, curing and foaming chemistry, production methods, morphology, properties, and applications is presented and discussed.

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Section: Properties Of Rubber Foamsmentioning

confidence: 99%

Chemistry, Processing, Properties, and Applications of Rubber Foams

Rostami‐Tapeh‐Esmaeil

Vahidifar

Esmizadeh

et al. 2021

Polymers

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“…This concept was applied to thermoplastics, elastomers, and thermosets . Today, a large amount of different nanoparticles is available such as carbon nanotube, nanosilica, and nanoclay (NC) which are frequently used in polymer matrices as reinforcing agents. Adding nanoparticles into elastomeric materials is one of the most suitable methods to improve the properties of the host matrix .…”

Section: Introductionmentioning

confidence: 99%

Morphological, rheological, and mechanical properties of hybrid elastomeric foams based on natural rubber, nanoclay, and nanocarbon black

et al. 2019

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In this study, compression molding was used to produce elastomeric nanocomposite foams based on natural rubber (NR) with a hybrid reinforcing system containing organo-modified nanoscale (NC) and nanocarbon black (NCB). The effect of NC content (0-10 part per hundred rubber, phr) on the curing behavior, as well as the morphological and mechanical properties of elastomeric foams containing 10 phr of NCB was determined. Transmission electron microscopy and X-ray diffraction results showed that NC exfoliation occurred at low NC concentration (less than 5 phr), while increasing NC content up to 5 phr led to aggregation. Rheological data revealed that increasing the NC content up to 10 phr gradually changed the curing parameters such as 50% shorter scorch and curing time, two times faster curing rate, as well as higher initial (35%) and final (35%) torque. Scanning electron microscopy analysis also showed that increasing NC content from 0 to 5 phr produced foams with more uniform small cells, while 7 phr of NC changed the foam structure into two areas composed of different cell sizes and different cell densities. Higher NC content (10 phr) led to broken cell walls. With nanoparticles, higher foam modulus (83%) and hardness (104%) were observed. Finally, NC addition was found to improve the NR's thermal and thermooxidative resistance while the sound absorption coefficient was constant. K E Y W O R D Sfoams, hybrid composites, nanocarbon black, nanoclay, natural rubber

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“…Most of these systems involve polypropylene (PP)/ethylene‐propylene‐diene rubber loaded with conductive carbon black (CB), 10–14 expanded graphite, 15,16 and carbon nanotube (CNT) 17–19 . Other few examples of conductive TPV include poly(vinylidene fluoride)/epoxidized natural rubber (ENR) loaded with CB, 20 copolyamide (COPA)/ENR loaded with CNT, 21 and linear low‐density polyethylene/reclaimed rubber with CNT 22 …”

Section: Introductionmentioning

confidence: 99%

Attaining low percolation threshold in conductive polypropylene/nitrile rubber thermoplastic vulcanizates using carbon nanotube

Gabino

Soares

Silva

2020

J of Applied Polymer Sci

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Electrically conductive thermoplastic vulcanizates (TPV) based on polypropylene (PP)/nitrile rubber (NBR) blends loaded with multiwalled carbon nanotube (CNT) were prepared by dynamic vulcanization. CNT was incorporated into the system using two different mixing sequences: (i) one‐step method, by adding CNT after the PP and NBR and (ii) two‐steps method involving a previous PP/CNT master batch. Scanning electron microscopy and transmission electron microscopy were used to analyze the morphology of the nanocomposites. Dynamic‐mechanical analysis and rheological properties were also used for characterizing the TPV and TPE samples. Both mixing strategies favored the location of the CNT inside the PP phase. The one‐step approach resulted in a percolation threshold as low as 0.19 vol% with conductivity value of 0.04 S m−1 for the system loaded with only 0.50 vol% of CNT. The electromagnetic interference shielding effectiveness and microwave absorbing properties were evaluated in the X‐band frequency range. The TPV samples prepared by both methods displayed an overall electromagnetic attenuation of around 70%.

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Thermoplastic vulcanizate nanocomposites based on polyethylene/reclaimed rubber: A correlation between carbon nanotube dispersion state and electrical percolation threshold

Cited by 16 publications

References 46 publications

Chemistry, Processing, Properties, and Applications of Rubber Foams

Chemistry, Processing, Properties, and Applications of Rubber Foams

Morphological, rheological, and mechanical properties of hybrid elastomeric foams based on natural rubber, nanoclay, and nanocarbon black

Attaining low percolation threshold in conductive polypropylene/nitrile rubber thermoplastic vulcanizates using carbon nanotube

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