Processing, structure, and properties of multiwalled carbon nanotube–poly(phenylene sulfide) composite fibers

Zeng, Lei; Mou, Hao; Qiao, Yu; Gong, Chen; Xu, Jianjun; Liu, Pengqing

doi:10.1002/app.44609

Cited by 9 publications

(10 citation statements)

References 24 publications

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“…Meanwhile, the effects of H-CNTs migration behaviors during the blending process of ternary system, H-CNTs location and different H-CNTs additions on the structure, phase morphologies and properties of PPS/PA 66 melt-spun fibers were also studied. 41 The phase morphologies and dispersed phase size of PPS/PA 66 blends with different H-CNTs additions obtained from different blending orders were characterized by scanning electron microscopes (SEM). The rheological properties and crystalline properties were analyzed by high-pressure capillary rheometer, differential scanning calorimeter (DSC), respectively.…”

Section: Introductionmentioning

confidence: 99%

“…Then, a series of ternary resins were prepared into fibers based on melt spinning technology. Meanwhile, the effects of H‐CNTs migration behaviors during the blending process of ternary system, H‐CNTs location and different H‐CNTs additions on the structure, phase morphologies and properties of PPS/PA 66 melt‐spun fibers were also studied 41 . The phase morphologies and dispersed phase size of PPS/PA 66 blends with different H‐CNTs additions obtained from different blending orders were characterized by scanning electron microscopes (SEM).…”

Section: Introductionmentioning

confidence: 99%

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The effects of carbon nanotubes selective location on the structures and properties of polyphenylene sulfide/polyamide 66 fibers

Zeng

Zhang

et al. 2022

J of Applied Polymer Sci

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Carboxyl modified carbon nanotubes (H‐CNTs) are added into 10 wt%‐polyamide 66/90 wt%‐polyphenylene (10‐PA 66/90‐PPS) blending system to improve the compatibility of blends. In order to investigate the effects of H‐CNTs selective location and H‐CNTs addition on the structures, morphologies, and properties of PPS/PA 66 composite fibers, three blending orders among H‐CNTs, PPS, and PA 66 are applied in the blending extrusion of ternary resins. The structures, morphologies, and properties of composite fibers are characterized via scanning electron microscopy, transmission electron microscopy, high‐pressure capillary rheometer, differential scanning calorimeter, tensile test, and dry heat shrinkage test. Experimental results indicate that the migration of H‐CNTs from PPS phase to the interface between PPS and PA 66 results in the increases of the crystallinity of PPS, the tensile strength and the high‐temperature resistance of ternary fibers. When H‐CNTs are blended with PA 66 firstly, the locking effects of H‐CNTs causes a phase‐inversion phenomenon, where major component PPS forms dispersed phase and minor component PA 66 forms continuous phase. Even though this phenomenon weakens the mechanical properties and the high‐temperature resistance of composite fibers, the shrinkage of composite fibers at high temperature is improved.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The effects of carbon nanotubes selective location on the structures and properties of polyphenylene sulfide/polyamide 66 fibers

Zeng

Zhang

et al. 2022

J of Applied Polymer Sci

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“…[3][4][5][6][7][8][9][10][11][12] PPS shows significant physical, mechanical, and chemical properties such as high decomposition temperature, dimensional and high temperature stability, flame resistance, high tribological properties, chemical and corrosion resistance, low water absorption, etc. [3][4][5]7,8,11,[13][14][15] Owing to its superior features, it finds many applications progressively such as battery, aerospace, automotive, machinery, telephone, electric and electronic, etc. 3,12,14,[16][17][18] However, usage of PPS is limited by its high price and weakness of toughness.…”

Section: Introductionmentioning

confidence: 99%

Investigation of mechanical and tribological behaviour of expanded perlite particle reinforced polyphenylene sulphide

Şahin

Çetin

Sınmazçelik

2021

Proceedings of the Institution of Mechanical Engineers, Part L:

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In this study, polyphenylene sulphide was used as a matrix material due to its superior engineering properties. Expanded perlite is formed substantially from silica oxides, and it is a volcanic based and porous structure material. Its low price and low density make it very usable as a filler material. For this reason, expanded perlite reinforced polyphenylene sulphide matrix composites were prepared at various weight ratios (0, 1, 3, 5, and 10 wt%). Mechanical and tribological characterizations were done with tensile tests, hardness measurements, solid particle erosion, ball on disc, and scratch tests. According to the tensile test results, a synergistic effect was observed in mechanical properties by using perlite as a reinforcing agent. As expected, perlite reinforcement resulted in an increase in the modulus of 54% in composites. As well as tensile strength of the composite increased by approximately 13%. Furthermore, the perlite particle reinforcement improved the adhesion resistance by 73% and the scratch resistance by 30%. On the other hand, especially at low impact angles, perlite particle reinforcement decreased the erosive wear resistance of the pure polyphenylene sulphide polymer by 50%. Furthermore, expanded perlite reinforcement decreased the plastic deformation ability of polyphenylene sulphide. In consequence of this study, it has been found that expanded perlite particles can be used as an alternative filler instead of conventional reinforcing particles.

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“…In the last decades, extensive researches have been performed on the preparation, structure, and performance of PPS fibers. 8 –11 Only a few researches on the preparation of oxidative PPS fibers have been reported. The antioxidative emulsions are prepared by nanoparticles, coupling agents, and antioxidants in a Chinese patent, 12 which can be used to form a protective shield on the surface of PPS melt spinning fibers by immersion process.…”

Section: Introductionmentioning

confidence: 99%

Preparation and characterization of polyphenylene sulfide/graphene nanoplatelets composite fibers with enhanced oxidation resistance

Xing

et al. 2019

High Performance Polymers

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Composite masterbatches of polyphenylene sulfide (PPS) with functionalized graphene nanoplatelets (GNPs) were prepared by melt blending via a twin-screw extruder. The structure and morphology of composite masterbatches were characterized by scanning electron microscopy and X-ray diffraction analysis. The PPS/functionalized GNPs composite fibers were then manufactured by a self-made spinning equipment via melt spinning. The oxidation resistance and other properties of PPS composite fibers were also examined. The results showed that the pure PPS fibers exhibited smooth surface, whereas the surface of PPS/functionalized GNPs composite fibers was rough. The addition of functionalized GNPs could be acted as heterogeneous nucleating agents to improve the crystallization and increase the degree of crystallinity. The retention rate of breaking strength of PPS/functionalized GNPs composite fibers could maintain up to 85% after the oxidation treatment. The improvement in the oxidation resistance of PPS/functionalized GNPs composite fibers is the results of comprehensive effects characterized by the X-ray photoelectron spectroscopy analyses. The addition of functionalized GNPs could limit the damage of the C–S group and retard the generation of sulfuryl groups (–SO–) during the oxidation treatment. The chemical combination of the elements sulfur (S) and oxygen (O) could also be restricted, thus weakening the oxidation activity.

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Processing, structure, and properties of multiwalled carbon nanotube–poly(phenylene sulfide) composite fibers

Cited by 9 publications

References 24 publications

The effects of carbon nanotubes selective location on the structures and properties of polyphenylene sulfide/polyamide 66 fibers

The effects of carbon nanotubes selective location on the structures and properties of polyphenylene sulfide/polyamide 66 fibers

Investigation of mechanical and tribological behaviour of expanded perlite particle reinforced polyphenylene sulphide

Preparation and characterization of polyphenylene sulfide/graphene nanoplatelets composite fibers with enhanced oxidation resistance

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