Plasma surface modification of advanced organic fibres

Brown, James R.; Chappell, P. J. C.; Mathys, Z.

doi:10.1007/bf02402964

Cited by 49 publications

(6 citation statements)

References 22 publications

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“…Biswas et al [9] observed an increase in the roughness of para-aramid fibers with time of activation at atmospheric pressure plasma (4 kW, 30 s, 1 min, 2 min, 3 min). Brown et al [23], by treating the para-aramid fabric with NH 3 plasma (100 W from 0.25-20 min) observed an increase in surface fibrillation. Chen et al [24] investigated the effect of atmospheric pressure plasma (720 W) on surface topography changes of para-aramid 3D fabric subsequent layers.…”

Section: Sem/eds Analysismentioning

confidence: 98%

Influence of Low-Pressure RF Plasma Treatment on Aramid Yarns Properties

et al. 2020

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The aim of the study was to modify the surface free energy (SFE) of meta- (mAr) and para-aramid (pAr) yarns by their activation in low-pressure air radio frequency (RF) (40 kHz) plasma and assessment of its impact on the properties of the yarns. After 10 and 90 min of activation, the SFE value increased, respectively, by 14% and 37% for mAr, and by 10% and 37% for pAr. The value of the polar component increased, respectively by 22% and 57% for mAr and 20% and 62% for pAr. The value of the dispersion component for mAr and pAr increased respectively by 9% and 25%. The weight loss decreased from 49% to 46% for mAr and 62% to 50% for pAr after 90 min of activation. After 90 min, the specific strength for mAr did not change and for pAr it decreased by 40%. For both yarns, the 10 min activation in plasma is sufficient to prepare their surface for planned nanomodification.

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Section: Sem/eds Analysismentioning

confidence: 98%

Influence of Low-Pressure RF Plasma Treatment on Aramid Yarns Properties

et al. 2020

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“…More widely used methods aim at the functionalization of the fiber surface. For AF and CF acidic oxidation , fluorination , and plasma treatment are described. For CF also ozone treatment or electrochemical oxidation are used.…”

Section: Fiber/matrix Interactionmentioning

confidence: 99%

Synthetic fibers and thermoplastic short-fiber-reinforced polymers: Properties and characterization

2013

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Among the synthetic fibers, glass fibers (GF) are most widely used in thermoplastic short‐fiber‐reinforced polymers (SFRP), as they offer good strength and stiffness, impact resistance, chemical resistance, and thermal stability at a low price. Carbon fibers (CF) are applied instead of GF, when highest stiffness is required. Other types of synthetic fibers like aramid (AF), basalt (BF), polyacrylonitrile (PAN‐F), polyethylene terephthalate (PET‐F), or polypropylene fibers (PP‐F) are rarely used in SFRP, although they offer some advantages compared with GF. The aim of this article is, to give an overview of various fiber types with regard to their mechanical properties, densities, and prices as well as the performance of their thermoplastic composites. The mechanical properties are presented as Ashby plots of tensile strength versus tensile modulus, both in absolute and specific (absolute value divided by density) values. This overview also focuses on modification of fiber/matrix interaction, as interfacial adhesion has a huge impact on composite performance. A summary of established methods for characterization of fibers, polymers, and composites completes this article. POLYM. COMPOS., 35:227–236, 2014. © 2013 Society of Plastics Engineers

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“…However, the interfacial strength is too weak to raise total performance of the composite, though some surface modification methods have been proposed, including plasma treatment [1,2] and chemical modification [3,4]. These modification methods cause the fibrillation of fiber and result in the reduction of fiber strength.…”

Section: Introductionmentioning

confidence: 99%

Interfacial reinforcement in composites with PPT aramid fiber modified by network-intercalation method

Ohnishi¹,

Fujioka²,

Kosuge³

et al. 2004

Composite Interfaces

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A novel surface treatment for poly(p-phenylene telephthalamide) (PPTA) fiber is performed with silanes and urethane binder that are usually used as sizes for glass fiber treatment. The PPTA used for the surface treatment is modified by a spinning process to make the gaps between PPTA crystallites open. In this treatment, supercritical carbon dioxide fluid method is used to impregnate the sizing molecules into open gaps in PPTA fiber. After the impregnation, the fiber is heated at 100-170 • C to make the gaps close and turn open-gapped fiber to the normal type of PPTA modified with sizes. The interfacial shear strength of fiber to epoxy resin is measured by microdroplet method. The modified PPTA improves the interfacial shear strength by ca. 67% to the interfacial shear strength given by normal PPTA without treatment. Those improvements are 33% without heating, 18% with only silanes, and 12% with only urethane instead of the mixture of silane and urethane. In addition, the fiber strength shows no remarkable decrease after the treatment.

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Plasma surface modification of advanced organic fibres

Cited by 49 publications

References 22 publications

Influence of Low-Pressure RF Plasma Treatment on Aramid Yarns Properties

Influence of Low-Pressure RF Plasma Treatment on Aramid Yarns Properties

Synthetic fibers and thermoplastic short-fiber-reinforced polymers: Properties and characterization

Interfacial reinforcement in composites with PPT aramid fiber modified by network-intercalation method

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