JPH03220335A - Fire-resisting fiber yarn and its use - Google Patents

Abstract

PURPOSE: To produce a textile yarn excellent in wear resistance, fracture resistance and uniformity in fracture resistance by adopting a core formed from a ply yarn comprising double-threaded multi-filaments in a fire-resistant textile yarn comprising a core formed from an inorganic filament surrounded by aramid fibers. CONSTITUTION: A fire-resistant textile yarn having a fineness of 30-55 tex and capable of being woven as a warp yarn and a weft one is produced by winding fibers formed entirely or in part from aramid resin (preferably formed from 50 wt.% aramid fiber and 50 wt.% viscose fiber) around a core formed from a ply yarn comprising double-threaded inorganic multi-filaments (e.g. glass filaments or the like) so as for the core content to be 10-30 wt.% and so as for the core to be surrounded by the above fibers.

Description

Detailed Description of the Invention [Industrial Application Field] The present invention comprises a core material made of inorganic filaments arranged in a non-twisted state in a proportion of 10 to 30% by weight, and The present invention relates to a fire-resistant fiber yarn consisting of a plurality of fibers made of aramid resin spun around a core material and having a fineness of 30 to 55 tex. The invention also relates to the use of said fire-resistant fiber yarn.

[Conventional technology]

A thread as described above has already been proposed in PR 2,599,762. Various tests carried out on this yarn have revealed several shortcomings, a solution to at least some of which is proposed in the present invention.

[Problems to be Solved by the Invention] To this end, the first object of the present invention is to provide a fiber yarn that can overcome the drawbacks of the conventional yarns, and the use of the fiber yarn is also an object of the present invention. This is the purpose of

[Means to solve the problem]

The object of the present invention is to form a core material made of inorganic filaments arranged in a non-twisted state at a ratio of 10 to 30% by weight, and an aramid resin spun around the core material so as to at least partially surround the core material. Consisting of multiple fibers, 30~
This is achieved by a refractory fiber yarn having a fineness of 55 tex, characterized in that the core is constituted by a two-strand twisted yarn of multifilaments.

The present invention also provides for use in conventional textiles in which the refractory fiber system of the present invention is used as warp and weft yarns of the same thickness.

The fiber yarns of the present invention exhibit excellent abrasion resistance and the surrounding fibers adhere better to a core composed of multifilament strands than monofilament strands. Also, the break resistance of the fiber yarns as well as the uniformity of the break resistance are improved as well.

Other advantages of the invention will become apparent from the description below.

When spinning fibers covering the core material, which is the object of the present invention, the method of keeping the core material in an axially untwisted state is carried out using a spinning machine manufactured by FEHRER.
(Dref m ). With this method, the peripheral fibers, which are thin fibers, are wrapped around the core material, which can also be done without axial twisting, i.e., by classical spinning methods. Therefore, for a yarn having a fineness of 30 to 55 tex, it is possible to use glass fiber monofilament twist yarn corresponding to 10 to 30 percent of the yarn.

Dref ■ Device selection is Dref U (Dref II
) device makes it possible to obtain fiber yarns that are thinner than those produced with the device;
Furthermore, in the case of spinning using long fibers, it is possible to spin fiber yarns up to 20 tex.

〔Example〕

Various fiber systems were made according to the examples provided below.

EXAMPLE 1 A coating giving a green tint 2 made by Societe Chavanoz of the Porsche Group, 163 Pour Bart des Etazny, 69009 Lyons, France.
A 50 tex fiber yarn with a glass core formed from two glass monofilament strands of x 5.5 tex was prepared. The glass filament twist is equal to 22% by weight of the fiber yarn.

The fibers spun around this core are 50% Rhδne Poulenc T.
ex-tile) (a fire-resistant polyamide-imide polymer) and 50% viscose flame retardant (V
iscoseFlame Retardant) (This is a Societ 6 a
colored fibers in bulk or silk form supplied by U-Trichienne Lenzing).

Approximately 70% of the total fibers are arranged parallel to the core and approximately 30% are wrapped around it.

Example 2 A 42 tex fiber yarn with a glass core formed from two multifilament strands of 2 x 5.5 tex, colored orange by coating, manufactured by Shavano was prepared. The glass multifilament twist is equal to 26% by weight of the fiber yarn.

The fibers surrounding the core material are meta-aramid fibers 5 commercially available as Corenx (trademark) by Tijin, Japan.
0% and 50% of the viscose flame retardant used in Example 1. Approximately 70% of the fibers are oriented parallel to the core and approximately 30% are wrapped around the core.

Example 3 A fiber yarn of 55 tex including a core made of twisted glass multifilament yarn similar to Example 1 was produced. This twist corresponds to 20% by weight of the fiber yarn.

The fibers surrounding the core are 67% viscose flame retardant (the same fibers used in the examples above) and are commercially available under the name P-83™ by Autorisienne Lanzan. 33% refractory fiber made from copolyimide. As in the previous example, approximately 70% of the fibers are arranged parallel to the core of the fiber thread, and approximately 30% of the fibers are wrapped around the core.

The results obtained with these fiber yarns show a considerable improvement compared to those obtained with fiber yarns containing a monofilament glass fiber core, 1. This also applies to fabrics made from the fiber yarns of the present invention. In addition to the above-mentioned improvements in the fiber yarns themselves, good coverage of the fiber yarns was also confirmed. Fiber yarns can also be further improved by coating monofilaments,
During dyeing, the fiber threads blend better with the fibers that cover them.

〔Effect of the invention〕

Due to the above-mentioned improvements in the fiber threads and their high abrasion resistance, it is possible to produce fabrics in which the warp threads have the same thickness as the weft threads and the proportion of inorganic filaments is the same.

This clearly offers a number of advantages.

In manufacturing textiles, it is actually easiest to work with the same fibers as warp and weft. Moreover, it has been found that the mechanical resistance of the fabric in the warp direction is improved, and the inorganic filament core material is suitable for its mechanical resistance due to its excellent coverage and excellent abrasion resistance of the fiber yarns, which are the objects of the present invention. is the same as the weft direction. This fiber yarn can be particularly useful for producing textiles and textiles.

Claims (1)

[Scope of Claims] 1. A core material made of inorganic filaments arranged in a non-twisted state at a proportion of 10 to 30% by weight, and an aramid resin spun around the core material so as to at least partially surround the core material. A fire-resistant fiber yarn having a fineness of 30 to 55 tex, characterized in that the core material is composed of two multifilament strands twisted together. fiber yarn. 2. A fire-resistant fiber yarn according to claim 1, characterized in that it comprises 50% aramid fibers and 50% viscose fibers. 3. The fire-resistant fiber yarn of claim 1, comprising 3.67% viscose fibers and 33% polyimide fibers. 4. A fire-resistant fiber yarn according to claim 1, characterized in that it comprises 50% polyamide-imide fibers and 50% viscose fibers. 5. The fire-resistant fiber yarn according to claim 1, wherein the multifilament is colored. 6. A refractory fiber yarn according to any one of claims 1 to 5, characterized in that about 70% of the fibers are arranged parallel to the core and about 30% are wrapped around the core. . 7. Use of the fire-resistant fiber yarn according to claim 1 for the production of conventional textiles, characterized in that the warp and weft have the same thickness. 8. Use of the fire-resistant fiber yarn of claim 6 for making a twill fabric.