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Polymer Science, Series D
Published in: Polymer Science, Series D 4/2023

01-12-2023

A Study of the Properties of Mineral, Chemical, and Vegetable Fibers

Authors: P. A. Medvedev, A. N. Blaznov, I. V. Cheremukhina, Z. G. Sakoshev, G. S. Zadvornykh, E. G. Sakoshev, V. V. Firsov

Published in: Polymer Science, Series D | Issue 4/2023

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Abstract

Comparative tests of the following fibers are conducted under the same conditions: mineral (basalt, glass), carbon, chemical (polycaproamide, polyacrylonitrile, viscose fibers), and vegetable (bast fibers of linen, hemp, nettle). The diameter of a monofiber, linear density, breaking strength of a roving (a bundle of fibers) and microplastics, breaking tenacity, and gain ratio are assessed. Glass and basalt fibers have the highest linear density of 1200–2500 tex; carbon, 378 tex; chemical, 183 tex (except for PANF, which has 826 tex); and bast vegetable fibers, 440–630 tex. The breaking tenacity for glass rovings and basalt rovings is comparable of 240–264 mN/tex and is the highest of 597 mN/tex for carbon rovings; the gain ratio is 2–2.25. For chemical fibers, the breaking tenacity is 282–323 mN/tex (92 mN/tex in viscose ones) and the gain ratio is 0.5–0.9. Of vegetable fibers, the highest breaking strength of 93–102 mN/tex is in the fibers of linen and hemp, which exceeds this parameter for a viscose fiber; the gain ratio is 1.6 in hemp and 4.39 in linen. In fibers of nettle, the results are the lowest among vegetable fibers.
previous article Influence of Machining Modes and Negative Temperature on the Static Bending Strength of Carbon Fiber Reinforced Plastics

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Metadata
Title
A Study of the Properties of Mineral, Chemical, and Vegetable Fibers
Authors
P. A. Medvedev
A. N. Blaznov
I. V. Cheremukhina
Z. G. Sakoshev
G. S. Zadvornykh
E. G. Sakoshev
V. V. Firsov
Publication date
01-12-2023
Publisher
Pleiades Publishing
Published in
Polymer Science, Series D / Issue 4/2023
Print ISSN: 1995-4212
Electronic ISSN: 1995-4220
DOI
https://doi.org/10.1134/S1995421223040226

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